Apparatus and methods for attaching objects to trees

ABSTRACT

Devices and methods for attaching objects to living trees. Various forms of the devices employ a flexible member and mounting member that are configured to be looped and secured around a tree portion at a beginning of a predetermined time period. The mounting member and flexible member are configured to slide relative to each other to accommodate growth of the tree portion such that the device remains secured to the tree portion for at least the duration of the predetermined period of time without the need for human intervention. In other embodiments, the mounting member is integrally formed with the object or no mounting member is employed.

CROSS REFERENCE TO RELATED APPLICATIONS

This non-provisional patent application claims the benefit of andpriority under 35 U.S.C. §119(e) from U.S. Provisional PatentApplication Ser. No. 61/578,597, filed Dec. 21, 2011, the entiredisclosure of which is herein incorporated by reference.

FIELD OF THE INVENTION

The present application relates to devices and methods for attachingobjects to trees and, more particularly, to devices for suspending anobject such as a sign, a feeder, etc. from a growing tree withoutdamaging the tree.

BACKGROUND

Signs, for example, are commonly used to mark or delineate the boundarylines of forested properties. Depending upon the particular application,the signs may be used to prevent unauthorized trespass or they may beused to mark boundary lines for forestry or other various forms of landuse activities. Signs are also often used on publicly owned tracts offorest to inform the public of various rules and restrictions governingthe use of that particular piece of property or forestland.

Over the years, a variety of types of signs have been developed forattachment to trees. Such signs may be provided in different sizes,shapes and color schemes and are commonly fabricated from a variety ofdifferent materials ranging from metal, plastic, paper, fiber-reinforcedpaper, etc. Regardless of the size and type of sign employed, thetime-worn method typically used to attach such signs to trees generallyinvolves the use of nails. For example, when attaching a relativelyflexible paper or fiber-reinforced paper sign to a tree, a nail iscommonly placed in each corner of the sign to fasten it to the tree.Such approach effectively attaches the sign to the tree while preventingit from “flapping” in the wind. However, as the tree grows, the sign isforced away from the nails and often results in the tearing of the signfrom around the nails. Thus, it is not uncommon to find such signssimply hanging from one or two nails located on one side of the sign ina few short years after the sign has been attached to the tree.

Other sign attachment methods that have been employed in the pastfrequently involve the attachment of the flexible sign to a so-calledbacking board. Such backing boards are commonly made from plywood orsimilar material and are also attached to the tree with nails. The signis usually attached to the backing board by staples or tacks. While suchapproach avoids the problem of the sign tearing away from the tree asthe tree grows, it is still undesirable for several reasons. Forexample, after even just a few years in the elements, the wooden backingboards tend to deteriorate. In addition, squirrels, porcupines and othertree climbing rodents often chew on the boards which leave the signswith little support.

Some signs are fabricated from metal or a polymer material and aresufficiently rigid and may not require a backing board for attachment tothe tree. Again, however, such signs are usually attached to the tree bytwo or more nails hammered through the center of the sign into the tree.

All of the above-mentioned approaches employ the use of nails or screwsto attach the sign to the tree. This use of such fasteners, however, isundesirable for several reasons. First, trees, like humans, aresusceptible to infection and disease when wounded. Nails that arecommonly used for sign attachment purposes can pierce the cambium orinner bark of the tree. The cambium is like the sub-dermis in a human.If that inner skin opens, infection and disease can get in and causesickness. Additionally, hammering nails into a tree causes stress to thetree as it tries to repair the injury. Stress makes trees more likely toattract infections and insects.

Another problem commonly associated with the use of nails for attachingsigns to trees is the potential catastrophic damage to loggers and theirsaw blades when the blades inadvertently contact a portion of a nailthat is embedded in the tree. As such, many loggers avoid harvestingtrees located on boundary lines. Such practice may result considerableeconomic loss to the property owner. Furthermore, nails made from steelor other corrosive metals will deteriorate from exposure to theelements. Over time, the head of the nail tends to deteriorate and falloff and thereby permits the sign to fall from the tree. If the sign isnot replaced or reattached, the nail shaft will remain in the treeportion To present an often undetectable hazard to the unwitting logger.Also, nail damage to trees negatively affects their value for subsequentuses such as furniture and other visually important applications.

In an effort to address the problem of nail corrosion and saw bladedamage caused by the use of nails in trees, some sign manufacturersrecommend the use of aluminum nails. Certainly aluminum nails may not beas susceptible to the corrosion problems encountered when usingfasteners fabricated from steel or other corrosive materials. Inaddition, aluminum nails are softer and are less-likely to damage a sawblade. However, aluminum nails are more susceptible to bending whenbeing driven into hardwood trees. Thus, the installer may often need todrive several aluminum nails into a tree portion To get one or morenails in a sufficient distance into the tree portion To retain the signor other object. Such approach results in the creation of multipleundesirable wounds to the tree which may damage the tree and harm itsultimate value.

In addition to the use of aluminum nails for attaching signs to treesfor boundary-marking purposes, some states and municipalities permit thelandowner to simply mark the boundary trees with paint. While thisapproach avoids the problems mentioned above associated with theattachment of signs to the trees, this approach is also less desirable.First, the most obvious reason is that such approach lacks the abilityto provide any information concerning the property, its owner, and/orany land use restrictions. In addition, the paint may become faded, orthe portion of tree bark containing the paint may eventually peel andfall off making the markings difficult to observe. Furthermore,depending upon the type and amount of paint used, the paint mayundesirably stress the tree leading to the intrusion of disease andinsects.

The aforementioned problems are not limited to the hanging of signs ontrees or other vertical objects. These problems may also be encounteredwhen hanging various other forms of objects from trees such as birdfeeders, ornaments, lights, etc.

Thus, the need exists for devices and methods for attaching objects suchas signs, feeders, etc. to growing trees without the disadvantages andproblems encountered when employing various attachment approachescommonly used in the past.

The foregoing discussion is intended only to illustrate various aspectsof the related art in the field of the invention at the time, and shouldnot be taken as a disavowal of claim scope.

SUMMARY

In accordance with at least one general form, there is providedapparatus for securing an object to a portion of a living tree. In atleast one form, the apparatus may comprise a cable that includes a firstend and a second end and has a length that is greater than an expectedcircumference of the tree portion at an end of a predetermined period oftime. The apparatus may further include a mounting member that has afirst portion that is secured to the first end of the cable. Themounting member may further have an opening therethrough that isdimensioned to receive the second end of the cable therethrough afterthe cable has been wrapped around a portion of the tree portion. Theapparatus may further include at least one friction generating memberthat is configured to be secured in a sliding frictional engagement ontoa portion of the cable that extends beyond the opening in the mountingmember to cinch the cable around the tree portion. The at least onefriction generating member may be dimensioned so as to interact with themounting member as the tree portion expands to thereby permit the cableportion to frictionally slip relative to the friction generating member.

In accordance with at least one other general form, there is providedapparatus for securing an object to a portion of a living tree at afixed elevation. In at least one form, the apparatus may comprise acable that includes a first end and a second end and has a length thatis greater than an expected circumference of the tree portion at an endof a predetermined period of time. The apparatus may further include amounting member that is secured to the first end of the cable and has afriction generating hole therethrough that is sized to receive therein aportion of the cable therethrough in sliding frictional engagement. Thefriction generating hole defines a hole axis. In addition, the apparatusmay further comprise an access slot that extends from an outer perimeterof the mounting member to the friction generating hole along a slot axisthat is substantially transverse to the hole axis to enable the cableportion to be inserted into the friction-generating hole in frictionalsliding engagement therewith to cinch the cable to the tree portion suchthat as the tree portion expands, the cable is configured tofrictionally slide through the friction generating hole while remainingcinched to the tree portion.

In accordance with still other general forms, there is providedapparatus for securing an object to a portion of a growing tree for atleast an expected period of time. In at least one form, the apparatusmay comprise a flexible member that has a length that is greater than anexpected circumference of the tree portion at an end of the expectedperiod of time. The apparatus may further comprise a mounting memberthat is configured to movably engage first and second portions of theflexible member such that when the first and second portions of theflexible member are extended around the tree portion in oppositedirections and brought into sliding frictional engagement with themounting member, the apparatus is secured to the tree portion. Inaddition, the first and second portions of the flexible member can moverelative to the mounting member without human intervention as the treeportion expands to enable the flexible member and mounting member tocontinue to be secured to the tree portion for at least the expectedperiod of time.

In accordance with at least one general form, there is provided a methodfor securing an object to a portion of a growing tree at a desiredheight. In at least one form, the method comprises wrapping a flexiblemember that has a mounting assembly attached to a first end thereofaround the portion of the growing tree. The method may further includemovably engaging a portion of the flexible member with the mountingassembly so as to cinch the flexible member to the tree portion at thedesired height such that the portion of the flexible member may movewithout human intervention relative to the mounting assembly to remaincinched to the tree portion as the diameter of the tree portionincreases. The method may further include supporting the object on atleast one of one of the flexible member and the mounting assembly.

In accordance with at least one other general form, there is provided amethod for securing an object to portion of a growing tree. In at leastone form, the method comprises wrapping a flexible member that has afirst end and a second end around a portion of the growing tree andattaching the first end of the flexible member to the object. The methodmay further comprise frictionally engaging a portion of the flexiblemember with a portion of the object such that the flexible member andobject are cinched to the tree portion and, as the tree portion expands,the flexible member frictionally slips relative to the portion of theobject to accommodate tree growth while remaining cinched to the treeportion.

In accordance with still another general form, there is provided amethod for attaching an object from a portion of a growing tree. In atleast one form, the method comprises wrapping a flexible member that hasa first end and a second end around a portion of the growing tree andslidably engaging a first portion of the flexible member with a firstportion on a mounting member. The method may further comprise slidablyengaging a second portion of the flexible member with a second portionon the mounting member such that the flexible member and mounting membercircumferentially grip the tree portion to be suspended therefrom andwherein, as the tree portion expands, the first and second portions ofthe flexible member frictionally slip relative to the first and secondportions, respectively. The method may further comprise supporting theobject on at least one of the flexible member and mounting member.

In accordance with at least one general form of the present invention,there is provided an apparatus for securing an object to a portion ofliving tree at a fixed elevation. In various forms, the apparatuscomprises a cable that has a first end and a second end. The inventionfurther comprises a mounting member that has a first portion that issecured to the first end of the cable. The mounting member further hasan opening in a second portion thereof that is dimensioned to receivethe second end of the cable therethrough. A ferrule is configured to besecured in a sliding frictional engagement onto a portion of the secondend of the cable that extends beyond the opening in the mounting member.The ferrule is dimensioned so as to be stopped by the mounting memberfrom passing through the opening.

In accordance with another general form of the present invention, thereis provided an apparatus for securing an object to a portion of agrowing tree at a fixed elevation for at least a predetermined period oftime. In various forms, the apparatus comprises a flexible member thathas a length that is greater than or equal to an expected circumferenceof the tree portion at an end of the predetermined period of time. Amounting member is configured to retainingly engage a first end of theflexible member and movably engage another portion of the flexiblemember such that, when the another portion of said flexible member isextended around the tree portion and brought into moving engagement withthe mounting member, the apparatus is secured to the tree portion. Suchconfiguration further permits the flexible member to move relative tothe mounting member without human intervention as the tree portionexpands to enable the flexible member and mounting member to continue tobe secured to the tree portion for at least the predetermined timeperiod.

In accordance with other general forms of the present invention, thereis provided a method for securing an object to a portion of a growingtree at a desired elevation above the ground. In at least one form, themethod comprises wrapping a flexible member that has a first end and asecond end around the portion of the growing tree and securing the firstend of the flexible member to a mounting member. The method alsocomprises movably engaging the second end of the flexible member withthe mounting member such that the second end may move relative theretowithout human intervention as a diameter of the tree portion increases.The method may further include supporting the object on the flexiblemember.

In accordance with still other general forms of the present invention,there is provided an apparatus for securing an object to a portion of agrowing tree for at least an expected period of time at a desiredelevation above the ground. In at least one form, the apparatuscomprises a flexible member that has a length that is greater than orequal to an expected circumference of the tree portion at an end of theexpected period of time. The apparatus further comprises a mountingmember that is configured to movably engage first and second portions ofthe flexible member such that when the first and second portions of theflexible member are extended around the tree portion in oppositedirections and brought into sliding frictional engagement with themounting member, the apparatus is secured to the tree portion. The firstand second portions of the flexible member can move relative to themounting member without human intervention as the tree portion expandsto enable the flexible member and mounting member to continue to besecured to the tree portion for at least the expected time period.

In accordance with other general forms of the invention, there isprovided an apparatus for securing an object to a portion of a growingtree for at least a predetermined period of time. In at least one form,the apparatus comprises a flexible member that has a length that isgreater than or equal to an expected circumference of the tree portionat an end of the predetermined period of time. The apparatus furtherincludes a mounting member that comprises a retainer body that isconfigured for attachment to a first end of the flexible member. A latchmember is attachable to the retainer body. The latch member isconfigured to movably receive a portion of the flexible membertherethrough. When the latch member is attached to the retainer body,the latch member is configured to apply frictional sliding resistance tothe portion of the flexible member that extends therethrough.

In connection with another general form of the present invention, thereis provided an object that is configured for attachment to a portion ofa growing tree at a desired elevation above the ground. In at least oneform, the object comprises a body that has a first portion and a secondportion. The invention further comprises a cable that has a first endthat is attachable to the first portion of the body and a second endportion that slidably extends through an opening in a second portion ofthe body. A ferrule is configured to be secured in a sliding frictionalengagement onto the second end portion of the cable that extends beyondthe opening in the body. The ferrule is dimensioned so as to be stoppedby the body from passing through the opening.

In connection with other general forms, there is provided a method forsecuring an object to a portion of a growing tree. In various forms, themethod comprises wrapping a flexible member that has a first end and asecond end around the portion of the growing tree. In addition, themethod comprises securing the first end of the flexible member to afirst portion of the object and movably engaging the second end of theflexible member with a second portion of the object such that the secondend may move relative thereto without human intervention as a diameterof the tree portion increases.

In accordance with another general form, there is provided a process formanufacturing an object to be secured to a portion of a growing tree. Inat least one form, the process comprises determining a period of timeduring which the object is to be secured to the tree and estimating acircumference of the portion of the tree at the end of the period oftime. The method further comprises providing a flexible member havinglength such that when a first end thereof is secured to the object, thelength of the flexible member in combination with the object issubstantially greater than the estimated circumference. A second portionof the flexible member is configured to extend around the tree portionand movably engage the object in slidable frictional engagement suchthat the second portion may frictionally slide relative thereto withouthuman intervention as a diameter of the tree portion increases.

In connection with another general form, there is provided a method forsecuring an object to portion of a growing tree. In at least one form,the method comprises wrapping a flexible member having a first end and asecond end around a portion of the growing tree and attaching the firstend of the flexible member to the object. The method further comprisesfrictionally engaging a portion of the flexible member with a portion ofthe object such that the flexible member and object combine tocircumferentially grip the tree portion to be suspended therefrom and,as the tree portion expands, the flexible member frictionally slipsrelative to the portion of the object.

In accordance with still other general forms of the invention, there isprovided a process for manufacturing a device for securing an object toa portion of a growing tree. In at least one form, the process comprisesproviding a mounting member that is configured to support the object.The process further comprises determining a period of time during whichthe object is to be secured to the tree and estimating a circumferenceof the portion of the tree at the end of the period of time. The processalso includes providing a flexible member that has a length such thatwhen a first end thereof is secured to the mounting member, an overalllength of the flexible member and mounting member exceeds the estimatedcircumference and wherein a second portion of the flexible member isconfigured to extend around the tree portion and movably engage themounting member in slidable frictional engagement such that the secondportion may frictionally slide relative thereto without humanintervention as a diameter of the tree portion increases.

In accordance with yet another general feature, there is provided amethod for securing an object to portion of a growing tree. In at leastone form, the method comprises wrapping a flexible member that has afirst end and a second end around a portion of the growing tree. Themethod further comprises attaching the first end of the flexible memberto a mounting member and frictionally engaging a portion of the flexiblemember with a portion of the mounting member such that the flexiblemember and mounting member combine to circumferentially grip the treeportion to be suspended therefrom. As the tree portion expands, theflexible member frictionally slips relative to the portion of themounting member. The method further comprises supporting the object onthe flexible member.

In accordance with another general form, there is provided a method forsecuring an object to a portion of a growing tree at a desired elevationabove the ground. In at least one form, the method comprises wrapping aflexible member that has a first end and a second end around the portionof the growing tree and movably attaching the first end of the flexiblemember to the object such that the first end may move relative theretowithout human intervention as a diameter of the tree portion increases.The method further includes movably attaching the second end of theflexible member to the object such that the object is cinched to thetree portion at the desired elevation and such that the second end maymove relative to the flexible member without human intervention as thediameter of the tree portion increases.

In accordance with still another form, there is provided a method forattaching an object from a portion of a growing tree. In at least oneform, the method comprises wrapping a flexible member that has a firstend and a second end around a portion of the growing tree and slidablyengaging a first portion of the flexible member with a first portion ona mounting member. The method further comprises slidably engaging asecond portion of the flexible member with a second portion of themounting member such that the flexible member and mounting membercircumferentially grip the tree portion to be suspended therefrom andwherein, as the tree portion expands, the first and second portions ofthe flexible member slip relative to the first and second portions ofthe mounting member. The method may further include supporting theobject on the flexible member.

In connection with another general form, there is provided an objectthat is configured for attachment to a portion of living tree at a fixedelevation. In at least one form, the object comprises a body that has afirst portion and a second portion. A flexible member has a first endthat is secured to the first portion of the body for extending around acircumference of the tree portion. Automatic adjustment means isconfigured to operably engage a second portion of the flexible memberfor automatically maintaining an amount of tension within flexiblemember as the tree portion expands.

In accordance with another form of the present invention, there isprovided an apparatus for securing an object to a portion of living treeat a fixed elevation. In at least one form, there is provided a flexiblemember for extending around a circumference of the tree portion. Theinvention further comprises automatic adjustment means that are operablyattached to the flexible member for automatically maintaining an amountof tension within the means for extending as the tree portion expands.The invention further comprises means for supporting the object thereonand interacting with at least one of the flexible member and theautomatic adjustment means.

In connection with another general form, there is provided a kit forattaching objects having at least two preformed holes therethrough toportions of growing trees for durations of expected installationperiods. In at least one form, the kit comprises a chart that containsrecommended cable lengths for a plurality of different tree species fora plurality of different installation periods. The kit further containsa bulk amount of cable that is sized to pass through at least two of theholes in each of the objects. The kit further comprises a plurality ofstop members that are configured to be non-movably attached to thecable. Each of the stop members are sized and shaped to prevent the stopmember from passing through one of the preformed holes in each of theobjects. The kit also includes a plurality of ferrules that are eachconfigured to be secured in a sliding frictional engagement ontoportions of the cable. Each of the ferrules are sized and shaped toprevent the ferrule from passing through another one of the preformedholes in each of the objects.

In accordance with other general aspects, there is provided a kit forattaching objects having at least two preformed holes therethrough toportions of growing trees for expected installation periods. In at leastone form, the kit comprises a chart that contains recommended cablelengths for a plurality of different tree species for a plurality ofdifferent installation periods. The kit further includes a plurality ofprecut cables wherein each of the cables is sized to pass through atleast two of the holes in each of the objects. Each of the precut cableshas a first end and a second end. The kit further comprises a pluralityof stop members that are each configured to be attached to acorresponding one of the precut cables. Each stop member is sized andshaped to prevent the stop member from passing through one of thepreformed holes in each of the objects. The kit further comprises aplurality of ferrules that are configured to be secured in slidingfrictional engagement onto a portion of a corresponding one of theprecut cables. Each of the ferrules is sized and shaped to prevent theferrule from passing through another one of the preformed holes in eachof the objects.

In accordance with still other general aspects, there is provided a kitfor attaching objects that have at least two preformed holestherethrough to portions of growing trees for expected installationperiods. In at least one form, the kit comprises a chart containingrecommended cable lengths for a plurality of different tree species fora plurality of different installation periods. The kit further includesa plurality of precut cables wherein each of the precut cable is sizedto pass through at least two of the holes in each of the objects. Eachof the precut cables has a first end with a stop member non-movablyattached thereto. Each stop member is sized and shaped to prevent thestop member from passing through one of the preformed holes in each ofthe objects. The kit further comprises a plurality of ferrules that areeach configured to be secured in a sliding frictional engagement ontoportions of the cable. Each of the ferrules are sized and shaped toprevent the ferrule from passing through another one of the preformedholes in each of the objects.

In accordance with other general aspects, there is provided a kit forattaching objects to portions of growing trees for expected installationperiods. In at least one form, the kit comprises a chart that containsrecommended cable lengths for a plurality of different tree species fora plurality of different installation periods. The kit further includesa plurality of mounting members that each have at least two preformedholes therethrough. Each mounting member is configured to support anobject. The kit further includes a bulk amount of cable that is sized topass through at least two of the holes in each of the hanger members.The kit also includes a plurality of stop members that are configured tobe attached to the cable. Each stop member is sized and shaped toprevent the stop member from passing through one of the preformed holesin each of the mounting members. The kit further comprises a pluralityof ferrules that are each configured to be secured in a slidingfrictional engagement onto portions of the cable. Each of the ferrulesare sized and shaped to prevent the ferrule from passing through anotherone of the preformed holes in each of the mounting members.

In connection with another general form, there is provided a kit forattaching objects to portions of growing trees for expected installationperiods. In at least one form, the kit comprises a chart that containsrecommended cable lengths for a plurality of different tree species fora plurality of different installation periods. The kit further includesa plurality of mounting members that are each configured to support anobject. Each of the mounting members has at least two preformed holesextending therethrough. The kit also includes a plurality of precutcables that are each sized to pass through at least two of the holes ineach of the objects. Each of the precut cables has a first end with astop member non-movably attached thereto. Each stop member is sized andshaped to prevent the stop member from passing through one of thepreformed holes in each of the objects. The kit further includes aplurality of ferrules that are configured to be secured in a slidingfrictional engagement onto corresponding portions of the cable. Each ofthe ferrules is sized and shaped to prevent the ferrule from passingthrough another one of the preformed holes in each of the objects.

FIGURES

Various features of the embodiments described herein are set forth withparticularity in the appended claims. The various embodiments, however,both as to organization and methods of operation, together withadvantages thereof, may be understood in accordance with the followingdescription taken in conjunction with the accompanying drawings asfollows.

FIG. 1 is a perspective view of an embodiment of the present inventioncoupled to a tree;

FIG. 1A is a front view of a portion of a mounting member of oneembodiment of the present invention;

FIG. 1B is a left side view of the mounting member of FIG. 1A supportinga first end of a flexible member therein;

FIG. 2 is a front view of the tree and embodiment depicted in FIG. 1;

FIG. 3 is a left side view of the tree and embodiment depicted in FIGS.1 and 2;

FIG. 4 is a top view of the embodiment of FIGS. 1-3 showing the tree incross-section;

FIG. 4A is another top view of the embodiment of FIGS. 1-3 with aplurality of bumper members attached to the flexible member;

FIG. 5 is another top view of the embodiment of FIG. 4 after thediameter of the tree has increased;

FIG. 5A is another top view of the embodiment of FIG. 5 with a pluralityof bumper members attached to the flexible member;

FIG. 6 is a front view of a portion of a mounting member of anembodiment of the present invention;

FIG. 7 is a front view of a bushing member of an embodiment of thepresent invention;

FIG. 8 is a side view of the bushing member of FIG. 7;

FIG. 9 is a cross-sectional view of the bushing member of FIGS. 7 and 8taken along line 9-9 in FIG. 7;

FIG. 10 is a top view of a bumper member of an embodiment of the presentinvention;

FIG. 11 is a front view of the bumper member of FIG. 10;

FIG. 12 is a top view of a bumper member of another embodiment of thepresent invention;

FIG. 13 is a front view of the bumper member of FIG. 12;

FIG. 14 is a perspective view of another embodiment of the presentinvention attached to a tree;

FIG. 15 is a front perspective view of a hanger member and flexiblemember of an embodiment of the present invention;

FIG. 16 is a perspective view of another embodiment of the presentinvention attached to a tree;

FIG. 17 is a perspective view of another embodiment of the presentinvention attached to a tree;

FIG. 18 is a partial exploded assembly view of the embodiment of FIG.17;

FIG. 19 is a perspective view of another mounting member embodiment andportion of a flexible member embodiment of the present invention;

FIG. 20 is a partial cross-sectional view of another mounting memberembodiment and portions of another flexible member embodiment of thepresent invention;

FIG. 21 is a partial cross-sectional view of another mounting memberembodiment and portions of another flexible member embodiment of thepresent invention;

FIG. 22 is a partial cross-sectional view of another mounting memberembodiment and portions of another flexible member embodiment of thepresent invention;

FIG. 23 is a perspective assembly view of the mounting member of FIG. 22and portions of the flexible member of FIG. 22;

FIG. 24 is a perspective view of another embodiment of the presentinvention attached to a tree;

FIG. 25 is another perspective view of the embodiment of FIG. 24 afterthe diameter of the tree has increased;

FIG. 26 is a perspective view of another embodiment of the presentinvention attached to a tree;

FIG. 27 is a top view of the embodiment of FIG. 26;

FIG. 28 is a perspective view of another embodiment of the presentinvention;

FIG. 29 is a top view of the embodiment of FIG. 28;

FIG. 30 is a perspective view of another embodiment of the presentinvention;

FIG. 31 is a top view of the embodiment of FIG. 30;

FIG. 32 is a top view of another embodiment of the present invention;

FIG. 33 is a perspective view of another embodiment of the presentinvention attached to a tree;

FIG. 34 is a top view of the embodiment of FIG. 33;

FIG. 35 is a perspective view of another embodiment of the presentinvention attached to a tree;

FIG. 36 is a top view of the embodiment of FIG. 35;

FIG. 37 is a top view of another embodiment of the present inventionattached to a tree portion with the tree portion shown in cross-section;

FIG. 37A is a top view of another embodiment of the present inventionattached to a tree portion with the tree portion shown in cross-section;

FIG. 38 is a partial cross-sectional view of a portion of the supportmember and flexible member of the embodiment of FIG. 37 showing aferrule on the flexible member;

FIG. 39 is a top view of another embodiment of the present inventionattached to a tree portion with the tree portion shown in cross-section;

FIG. 40 is a top view of another mounting member embodiment of thepresent invention;

FIG. 41 is a cross-sectional view of the mounting member of FIG. 40taken along line 41-41 in FIG. 40 and with a friction-generating memberof the present invention shown in phantom lines to illustrate therelationship between the outer diameter of the friction-generatingmember and the mounting member;

FIG. 42 is a front view of a friction-generating member or ferruleembodiment of the present invention;

FIG. 43 is a cross-sectional side view of the friction-generating memberembodiment of FIG. 42 taken along lines 43-43 in FIG. 42;

FIG. 44 is an exploded cross-sectional assembly view of a flexiblemember embodiment, a mounting member embodiment and a frictiongenerating member embodiment prior to assembly;

FIG. 45 is another exploded cross-sectional assembly view of thecomponents of FIG. 44 with the second end of the flexible memberextending through an opening in the bottom of the mounting member andwith the friction-generating member attached to a portion of theflexible member;

FIG. 46 is another exploded cross-sectional view of the components ofFIGS. 44 and 45 with the friction-generating member seated within thereceiving area in the mounting member;

FIG. 47 is a top view of another hanger member embodiment of the presentinvention;

FIG. 48 is a front view of the hanger member embodiment of FIG. 47;

FIG. 49 is a side elevational view of the hanger member embodiment ofFIGS. 47 and 48;

FIG. 50 is a top exploded assembly view illustrating attachment of anobject to the hanger member embodiment of FIGS. 47-49;

FIG. 51 is a front view of another hanger member embodiment of thepresent invention;

FIG. 52 is a cross-sectional view of a portion of a tree with theapparatus of FIGS. 44-46 attached thereto;

FIG. 53 is a top view of another embodiment of the present invention forattaching an object to a tree;

FIG. 54 is a front view of the apparatus of FIG. 53;

FIG. 55 is another top view of the apparatus of FIGS. 53 and 54illustrating a second end of a flexible member prior to engagement withthe mounting member of the apparatus;

FIG. 56 is another top view of the apparatus of FIGS. 53-55 after aportion of the flexible member has been engaged with the mountingmember;

FIG. 57 is a top view of another embodiment of the present invention forattaching an object to a tree;

FIG. 58 is a front view of another mounting member embodiment of thepresent invention;

FIG. 59 is another front view of the mounting member embodiment of FIG.58 with a second end of a flexible member prior to engagement with themounting member;

FIG. 60 is another top view of the apparatus of FIGS. 58 and 59 after aportion of the flexible member has been engaged with the mountingmember;

FIG. 61 is cross-sectional view of a portion of a tree with theapparatus of FIGS. 58-60 attached thereto;

FIG. 62 is an enlarged cross-sectional view of a portion of the tree andapparatus of FIG. 61;

FIG. 63 is a front view of another mounting member embodiment of thepresent invention;

FIG. 64 is a cross-sectional view of the mounting member of FIG. 63taken along line 64-64 in FIG. 63;

FIG. 65 is a front view of another mounting member embodiment of thepresent invention; and

FIG. 66 is a top view of the mounting member of FIG. 65.

Corresponding reference characters indicate corresponding partsthroughout the several views. The exemplifications set out hereinillustrate various embodiments of the invention, in one form, and suchexemplifications are not to be construed as limiting the scope of theinvention in any manner.

DESCRIPTION

Numerous specific details are set forth to provide a thoroughunderstanding of the overall structure, function, manufacture, and useof the embodiments as described in the specification and illustrated inthe accompanying drawings. It will be understood by those skilled in theart, however, that the embodiments may be practiced without suchspecific details. In other instances, well-known operations, components,and elements have not been described in detail so as not to obscure theembodiments described in the specification. Those of ordinary skill inthe art will understand that the embodiments described and illustratedherein are non-limiting examples, and thus it can be appreciated thatthe specific structural and functional details disclosed herein may berepresentative and do not necessarily limit the scope of theembodiments, the scope of which is defined solely by the appendedclaims. The particular features, structures, or characteristicsillustrated or described in connection with one embodiment may becombined, in whole or in part, with the features structures, orcharacteristics of one or more other embodiments without limitation.

It is estimated that there are 100,000 tree species throughout theworld. Trees can be identified to genus or species by a combination ofthe tree's shape and the characteristics of its bark, leaves, flowersand fruit. Bark is a tree's natural armor and generally protects thetree from external threats. However, the bark is also the tree's mostvulnerable part. The bark is continually renewed from within; itinsulates against the heat and cold and wards off insects. The innerbark is called the “phloem”. The phloem is a living tissue and carriesmanufactured food (sugars) from the leaves to the roots. The “cambium”layer, which is commonly only a few cells thick, is the regenerativelayer that gives birth to “xylem” to its inside and phloem to itsoutside. Thus, it annually produces new bark and new wood in response tohormones that pass down through the phloem with food from the leaves.

If the food-transporting phloem is severed all the way around the tree,food cannot be carried to the roots and they will eventually die.Indeed, one process employed to remove competition from unwanted treeswithout actually harvesting the tree is known as “girdling”. Girdlinginvolves severing the phloem layer completely around the tree so nonutrients can pass to the tree's roots. The tree slowly dies in place,opening up the forest canopy to permit more light to pass to adjacentdesirable trees. If the phloem layer is not completely severed aroundthe tree, nutrients can still flow through the un-severed portion andthe tree's adjacent cambial material may eventually overgrow the girdle.

Trees grow in diameter every year. The rate at which a tree grows indiameter is largely related to the species of tree, its environment andthe annual weather that it experiences. For example, the amount ofsunlight and rain available to it can effect the tree's growth rate.Other factors such as the quality and type of soil can also effect howfast a tree grows. Over the years, various methods and tables have beendeveloped for estimating how much a tree can be expected to growannually. See, e.g., Tree Growth Rate Table: Annual Percentage Growth byDr. Kim D. Coder, University of Georgia, December 1996, the entiredisclosure of which is herein incorporated by reference.

FIGS. 1-5 illustrate one embodiment of an apparatus 10 for hanging orsuspending an object 12 from a portion of a tree or other verticalobject, generally designated as T. In FIGS. 1-5, the object 12 isdepicted in phantom lines and may comprise a sign, for example. Avariety of different sign constructions and compositions are known. Forexample, the sign 12 may be fabricated from a metal material such asaluminum. Signs may also be fabricated from various types andthicknesses of polymer materials (flexible or rigid) or from variousforms of paper or fiber-reinforced paper.

In this embodiment, the apparatus 10 includes a mounting member 20 and ahanger member 30 that is configured to support the sign 12. Although theFigures depict the mounting member 20 and hanger member 30 as separatecomponents, it will be appreciated that the mounting member 20 andhanger member 30 may be integrally formed out of the same material. Itwill be further appreciated that the mounting member 20 and hangermember 30 may be provided in different shapes that are better suited tosupport a particular type of sign or other object.

In the illustrated embodiment, the hanger member 30 has a back portion31 that has support ledges 32 and support lips 34 formed thereon thatenable the sign 12 to be slid into or otherwise inserted therein. In atleast one embodiment, the hanger member 30 is fabricated from anon-corrosive metal material such as aluminum. The aluminum may have athickness that enables the user to bend the lips 34 inward intoretaining engagement with the sign 12 once it has been installed thereinto assist in retaining the sign 12 within the hanger member 30. In otherembodiments, the hanger member 30 may be fabricated from thicker metal,polymer material or other suitable material that is not sufficientlymalleable to facilitate such bending. In those cases, the support lips34 may be spaced from a back portion 31 of the hanger member 30 suchthat a sliding frictional fit is established between the sign 12, thelips 34 and the back portion 31. In still other embodiments, one or moreset screws (not shown) may be provided through one or more of the lips34 to retain the sign 12 in place once it has been installed in thehanger member 30. In still other embodiments, the hanger member 30 maybe substantially planar. In such embodiments, the sign 12 may be affixedto the hanger member 30 by a variety of different fastener arrangementssuch as, for example, clamps, screws, bolts, rivets, adhesive,double-sided tape, paper fastener brads, etc.

In at least one embodiment, the mounting member 20 comprises anelongated bar. For example, the mounting member 20 may comprise a pieceof aluminum material and be riveted, screwed, bolted, welded, glued,etc. to the hanger member 30. In other embodiments, the mounting member20 may be fabricated from steel (e.g., stainless or other forms ofpainted or galvanized steel) or other metal or polymer material, wood orother suitable material that may be similarly attached to the hangermember 30.

In various embodiments, the apparatus 10 further includes a flexiblemember 40 that has a first end 42 and a second end 44. In at least oneembodiment, the flexible member 40 comprises braided metal cable or wirerope. It is conceivable, however, that the flexible member 40 maycomprise other forms of cable or wire fabricated from a variety ofmaterials. It is further anticipated that, for at least someembodiments, the flexible member 40 may comprise a strap fabricated fromcloth, fiber, metal, polymer, rubber or various combinations of suchmaterials. The flexible member 40 may also comprise a solid wire orsimilar arrangement fabricated from metal or polymer. As will becomefurther apparent as the Detailed Description proceeds, the flexiblemember 40 should be sufficiently flexible to enable it to extend aroundat least a portion of the tree portion T as described below, yet havesufficient tensile strength when in use to avoid failure as the tree'sgirth continues to expand.

In the illustrated embodiment, the first end 42 of the flexible member40 is attached or affixed to a first end or portion 22 of the mountingmember 20. In at least one embodiment, wherein the flexible member 40comprises braided cable, the first end of the flexible member 40 extendsthrough a hole 23 in the first end 22 of the mounting member 20 and hasa lug or stop 46 attached thereto to prevent the flexible member 40 frompulling through the hole 23. The lug 46 may be fabricated from, forexample, aluminum or other metal or polymer material and be configuredto be non-movably crimped onto or otherwise affixed to the first end ofthe cable 40. It will be understood that other methods of fastening thefirst end 42 of the flexible member 40 to the first end 22 of themounting member 20 may be employed. For example, the first end 42 of theflexible member 40 may be permanently attached to the first end 22 ofthe mounting member 20 by welding or other suitable fastenerarrangements. In still other embodiments, the flexible member 40 may beclamped or glued to the first end 22 of the mounting member 20.

FIGS. 1A and 1B illustrate a portion of an alternative mounting member20′ wherein the first end 22′ has an irregular slot 23′ therein that hassomewhat sharp edges. The slot 23′ is formed by cutting the irregularshape in the first end 22′ of the mounting member 20′ and the one sideof the slot 23′ is bent slightly out of plane with the remaining portionof the mounting member 20′ to form a space therebetween that is sizedrelative to the first end 42 of the flexible member 40. Such arrangementenables the user to jam the first end 42 of the flexible member 40 downthrough the slot 23′ (arrow “D” in FIG. 1A) and be frictionally retainedtherein. That is, once the flexible member 40 has been seated into theslot 23′, the sharp edges dig into the flexible member 40 to prevent itfrom being inadvertently dislodged from the slot 23′.

In various embodiments, the flexible member 40 is configured to movablyengage a second end or portion 24 of the mounting member 20. Morespecifically, in the depicted embodiment, the flexible member 40 islooped around the backside of the tree portion T and engages a latch ortension relief mechanism 50 that is attached to or otherwise formed inthe second end 24 of the mounting member 20.

In at least one embodiment, the latch or tension relief mechanism 50comprises a bushing or insert 60 that is attached to the second end orportion 24 of the mounting member 20. For example, as shown in FIGS.6-9, the bushing 60 may have a flanged end 62 and a body portion 64 thatis sized to be inserted through a hole 25 in the mounting member 20. Inone embodiment, for example, a bayonet-type connection may be employed.For example, a pair of opposed retention tabs 65 are provided on thebody portion 64 of the bushing 60 that are spaced from the flanged end62 a distance that is substantially equal to the thickness of themounting member 20. The outer surface 66 of the portion of the body 64extending between the retention tabs 65 may be formed with a taper asshown in FIGS. 8 and 9. The bushing 60 further has an axial hole 68extending therethrough for receiving the flexible member 40 therein. Aslot 69 is provided through the body portion 64 and flanged end 62 toenable the user to insert a portion of the flexible member 40 into theaxial hole 68 during installation. Once the flexible member 40 has beeninserted into the hole 68 in the bushing 60, the bushing 60 may then beinserted into the hole 25 in the first end 22 of the mounting member 20.To do so, the retention tabs 65 are aligned with corresponding tabopenings 27 in the hole 25 and the bushing 60 is inserted therein.Thereafter, the bushing 60 is rotated to a position wherein the tabs 65are no longer aligned with the tab openings 27. In at least oneembodiment, each tab 65 has a cam surface 67 formed thereon such that asthe bushing 60 is rotated within the hole 25, the cam surfaces 67,interacting with corresponding portions of the mounting member 20, urgethe bushing 60 into the hole 25. As the tapered outer surface portion 66on the body portion 64 is drawn into the hole 25, the body portion 64 isforced into sliding frictional engagement with the portion of theflexible member 40 passing through the axial hole 68 to establish africtional sliding fit therebetween.

The bushing 60 may be installed in the above-described manner by themanufacturer or by the end user in the field. For example, when usingthe embodiment wherein the first end 42 of the flexible member 40 hasbeen attached to the first end 22 of the mounting member 20, once theuser passes the second end 44 of the flexible member 40 around thebackside of the tree portion T, it is passed through the hole 25 in thesecond end 24 of the mounting member 20 and is inserted through the slot69 into the hole 68 in the bushing 60. The user may then attach thebushing 60 to the mounting member 20 in the manner described above. Oncethe bushing 60 has been attached to the mounting member 20, the user canlocate the apparatus 10 at a desired height on the growing tree portionT and then cinch or secure the flexible member 40 around the treesufficiently tightly so as to retain it in position, yet not so tight asto cut through the outer layer of bark and into the inner bark andcambium layer. The flexible member 40 may be cinched or secured aroundthe tree portion T by pulling the second end 44 of the flexible member40 away from the mounting member 20. The remaining portion of theflexible member 40 is permitted to hang there to eventually be taken upas the tree continues to grow. Thereafter, and/or at any other suitabletime, the user may install the sign 12 in the hanger member 30 using anyof the various fastener arrangements described above. As the treecontinues to grow, the flexible member 40 will frictionally slidethrough the bushing 60 to accommodate such growth without any need forhuman intervention. When the circumference of the tree exceeds thelength of the flexible member 40 and retainer 20, the apparatus 10 mayfall from the tree portion To prevent any inadvertent damage to the treeas the tree portion T continues to grow. The apparatus may be reused ona smaller tree or the user may replace the original flexible member witha longer flexible member and reattach it to the tree portion.

In an alternative method wherein a mounting member 20′ is employed andthe bushing 60 has been installed therein by the manufacturer, the userwraps the flexible member 40 protruding from the bushing 60 around theback side of the tree “T” to bring the first end 42 of the flexiblemember adjacent to the slot 23′. The user then seats the first end 42 ofthe flexible member 40 down into the slot 23′. If necessary, the usermay pull enough of the flexible member 40 back through the bushing 60 toenable the first end 42 to cinch or secure the apparatus 10 to the treeportion T. Again, as the tree portion T continues to grow, the flexiblemember 40 will slide through the bushing 60 to accommodate such growthwithout any need for human intervention. When the circumference of thetree exceeds the length of the flexible member 40 and retainer 20member, the flexible member may completely pull through the bushingpermitting the apparatus to release from the tree portion T to avoiddamage thereto as the tree continues to grow. The apparatus may bereused on a smaller tree or the user may replace the original flexiblemember with a longer flexible member and reattach it to the treeportion.

Once installed in the manners described above, the flexible member 40retains the sign 12 in desired position on the tree portion Tat adesired elevation above the ground. As the tree grows, the flexiblemember 40 is permitted, by virtue of the sliding frictional fit with thelatch assembly 50, to slip relative thereto to accommodate the treegrowth. A range of sliding fits are contemplated. Preferably, thesliding frictional fit comprises the minimum amount of slidingfrictional fit required to enable the apparatus to be cinched inposition around the tree portion with sufficient retention force so asto retain the object to be hung thereon at a desired elevation above theground, yet not so tight as to cut through the outer layer of bark andinto the inner bark and cambium layer of the tree portion. Such fitfurther facilitates the remaining portion of the flexible memberprotruding out through the latch arrangement to slide relative theretowithout any subsequent human intervention so as to automaticallyaccommodate the growth of the tree portion without significantlydamaging the inner bark and cambium layer. The sliding frictional fitmay also enable the user to pull the flexible member out through thebushing 60 without the use of tools to detach the apparatus 10 from thetree portion T. The latch or tension relief mechanism 50 serves toautomatically relieve the tension that may build in the flexible memberto accommodate the expansion of the tree portion without humanintervention.

Such arrangements are distinguishable from the use of cloth or fabricstraps and locking buckles that are commonly used to attach devices suchas treestands to trees. These fabric strap and buckle arrangements aredesigned to lock the treestand to the tree and not slip. Such straps aregenerally fabricated from materials that are selected because theystretch very little when placed under tension. Thus, as the treecontinues to grow, the amount of tension builds in the strap. If leftunchecked, the strap may ultimately break or grow into the treesufficiently to damage the inner bark and cambial layer. To prevent thisfrom happening, the user must periodically inspect the strap andmanually release the buckle to relieve an amount of tension in thestrap.

Also, the use of various flexible member embodiments and tension reliefmechanisms disclosed herein is distinguishable from those applicationswherein a relatively elastic member such as a bungee cord, elastic strapor the like is simply wrapped around the tree and otherwise hooked orattached to the object. The ability of such arrangement to accommodatetree growth for the installation period is dependent upon the modulus ofelasticity of the strap that is employed. As the tree grows, the elasticstrap stretches under tension. Such tension, however, will continue tobuild as the tree grows to a point wherein the strap may, in extremecases, damage the tree or break. The flexible members and tension reliefmechanism(s) of various embodiments of the present invention serve toautomatically accommodate the estimated tree growth during a specifictime period without permitting tension to build within the flexiblemember to a magnitude that might damage the tree or cause the flexiblemember to fail before the end of the installation period.

Alternative latch/tension relief mechanisms are contemplated and areintended to be encompassed by at least some of the appended claims. Forexample, another latch or tension relief arrangement of the presentinvention comprises a hole provided through the second end or secondportion of the mounting member 20 that is sized to establish a slidingfrictional fit with the flexible member. The flexible member 40 may beinstalled through the hole by the manufacturer. In still otherembodiments, a slot may be provided through a portion of the mountingmember to enable the end user to introduce the flexible member into thehole in the field. A screw or other fastener arrangement may be employedto close the slot to retain the flexible member within the hole whileestablishing a desired amount of sliding frictional fit therebetween. Itwill be further appreciated that the holes in the various embodimentsthrough which the flexible member passes may be knurled if desired toestablish a desired amount of sliding frictional fit between themounting member and the flexible member.

The bushings and inserts disclosed herein may be fabricated from avariety of different metal, polymer, rubber or other suitable materials.The bushings may be attached to their respective mounting members by avariety of alternative methods. For example, the bushings may bepress-fit into their respective holes. They may be retained with theholes or openings in the mounting members by tabs, threads, welds,solder, adhesive, etc. In at least some embodiments, the amount ofsliding frictional fit attained between the bushing and the flexiblemember may be dependent upon the duration or amount of contact achievedbetween the bushing and the flexible member. That is, those bushingswith longer body portions may provide additional frictional contact withthe flexible member as it slides therethrough. Those bushings withshorter body portions may offer less frictional contact with theflexible member and therefore the magnitude of the sliding frictionalfit established between the flexible member and the bushing may besmaller. It will be further appreciated that the first end of theflexible member may be attached to the mounting member at various firstportions other than the first end thereof.

Alternative embodiments employ two latch or tension relief mechanisms50. In such embodiments, for example, the first end 42 of the flexiblecable 40 is passed through the second latch 50 supported in the firstend or portion 22 of the mounting member 20. Thus, as the tree grows,the first and second latches or tension relief mechanisms 50 willautomatically relieve tension in the flexible member 40 to accommodateadditional tree growth.

In still other embodiments, no separate support member or hanger isemployed. In such embodiments, for example, the latch(es) 50 areattached to or otherwise supported in the object itself. Thus, theflexible member 40 operably interfaces with the object (instead of thesupport member) and the latch(es) therein in the above-describedmanner(s).

Regardless of the number and type of latch or tension reliefmechanism(s) employed, the flexible member 40 may be sized such that,after being cinched or otherwise secured to the tree portion, theflexible member is permitted to protrude out of the latch(es) asufficient distance so as to accommodate the growth of the tree portionfor a desired period of time. As the tree portion continues to grow, theflexible member 40 continues to frictionally slip through the latch(es)50 to accommodate such growth without any human intervention whileretaining the object at the desired height above the ground untileventually all of the flexible member 40 pulls through the latch(es) 50,at which point the apparatus may fall from the tree or the originalflexible member may be replaced with a longer flexible member toaccommodate further tree growth.

The length of the flexible member employed may depend upon the amount oftree growth that is expected to occur over the duration of time that thesign or other object is expected to be suspended from the tree. In onealternative, for example, the desired installation period may be relatedto the amount of time that the sign is expected to last. For example,paper signs may be expected to last only a few years. Polymer signs andaluminum signs generally last for longer periods until the letteringthereon fades and portions or all of the lettering become illegible.Once the “installation period”, the “expected period”, or the“predetermined period” (the desired period during which the sign orother object is to remain suspended on the tree) has been determined,the amount of tree growth that is expected to occur during thatinstallation period is then estimated. That is, the circumference of thetree portion at the end of the installation period is estimated. Whenattached together in the various manners described above, the flexiblemember 40 and mounting member 20 must be sufficiently long enough in theaggregate to extend around the circumference of the tree portion at theend of the installation period and remain secured thereto at leastthrough the duration of the installation period.

By way of example only, assume the user desires to hang a sign for aperiod of ten years (installation period) on an oak tree portion Thathas an initial diameter of four inches. It is known that the particularspecies of oak is estimated to grow approximately one inch in diametereach year. Thus, at the end of the ten year period, it is estimated thatthe tree will now have a diameter of approximately fourteen inches(4″+10″). The circumference of the tree portion at the end of the tenyear period may then be calculated using the formula: πd, where:

π=3.14 . . . and

d=the ending diameter of the tree

Thus, in the present example, the tree portion is expected to have acircumference of approximately forty-four inches at the end of the tenyear installation period. In this example, assume that the distancebetween the first end 22 and the second end 24 of the mounting member 20is approximately six inches. As such, at a minimum, the flexible member40 should have a length of at least approximately thirty-eight inches(44″−6″=38″) to enable the mounting member 20 and flexible member 40 toaccommodate that amount of tree growth. However, because the growth rateof a tree has been estimated and can vary depending upon variouscharacteristics of the environment in which it is growing and theweather conditions it experienced over the ten year period, the user maywish to add a few more inches to the flexible member 40 to be reasonablyassured that the sign will remain attached to the tree portion at leastthrough the duration of the ten year period. For example, the user maywish to add a few inches to the flexible member to be relatively surethat the flexible member is long enough to accommodate the actual amountof tree growth to occur during the desired installation period. FIG. 4illustrates the apparatus attached to a tree portion having a startingcross-sectional diameter. FIG. 5 illustrates the apparatus 10 and thesame cross-sectional tree portion after the tree portion has expanded toa larger diameter. The latch 50 served to automatically relieve thetension in the flexible member without the need for human intervention.

As indicated above, in various embodiments, it may be desirable for the“sliding frictional fit” generated between the latch or tension reliefmechanism(s) 50 and the flexible member 40 to be of a sufficientmagnitude to cinch or otherwise secure the apparatus to the growing treeportion, yet permit the flexible member 40 to frictionally slip relativeto the latch 50 to accommodate the tree portion as it grows withoutcutting through and damaging the inner bark and cambium layer andwithout the need for human intervention or manipulation of the apparatusfor at least the duration of the installation period. As can be seen inFIGS. 4 and 5, there are considerable portions of the tree'scircumference that remain untouched by the mounting member 20 and theflexible member 40 which reduce any likelihood of completely severingthe phloem layer which could kill the tree.

FIGS. 4A and 5A illustrate use of a plurality of bumper members 80 onthe flexible member 40 to space the flexible member 40 away from thetree portion at locations around the tree which serve to further reduceany likelihood of inner bark damage. As can be seen in FIG. 10, forexample, in at least one embodiment, the bumper 80 has body portion 82that has a passage 84 therethrough that enables the flexible member 40to freely pass therethrough. The bumper 80 may be formed from a polymer,rubber, wood, metal, etc. that has an arcuate bumper surface 86 formedthereon that is intended to contact the tree portion without harming orgouging into the outer bark. FIG. 12 illustrates an alternative bumperembodiment 90 that is fabricated from a piece of arcuate metal strappingthat has holes 92 therethrough that are configured to permit theflexible member to freely pass therethrough. It will be understood thatthe various mounting members and hanger members disclosed herein may beformed with radiused contact portions designed to contact the treeportion and space most of the mounting member and/or hanger member awayfrom the tree bark.

FIG. 14 illustrates another apparatus 110 for hanging or suspending anobject such as a sign (not shown) from a portion of a tree portion T.This embodiment includes a mounting member 120 and a hanger member 130.As can be most particularly seen in FIGS. 14 and 15, the hanger member130 may comprise an extruded member (fabricated from for example, metalor polymer material) that has a centrally disposed channel 132 and tworaised planar attachment faces 134. For example, the hanger member 130may comprise a portion of a “hat channel furring strip” that isfabricated from galvanized steel, aluminum or other metal. Suchcomponent may, for example, be formed using conventional roll forming orextrusion techniques and processes. Other hanger members 130 may beformed from polymer materials. Double-sided tape 136 may be applied toeach attachment face 134 to facilitate easy attachment of a sign 12 orother object thereto. In other embodiments, the sign may be attached tothe hanger member 130 by clamps, rivets, screws, bolts, clips, adhesive,paper fastener brads, etc. The flexible member 140 may be attached tothe hanger member 130 by passing the flexible member 140 through holesprovided through the channel 132.

Turning to FIG. 14, it can be seen that in at least one embodiment, themounting member 120 has two opposing longitudinal slots 124, 126 thereinfor receiving portions of the flexible member 140 therein as shown. Inthe illustrated embodiment, the mounting member 120 has acylindrical-shaped body 122 and may be fabricated from, for example,flexible rubber or polymer material or a combination of such materials.The slots 124,126 may have a tapered shape as shown. The body 122 mayhave two opposing circumferentially extending grooves 128 therein thataccommodate corresponding spring clamps 129. Other forms of adjustableclamps (e.g., worm gear adjustable clamps, wire ties, etc.) could beused.

The flexible member 140 may comprise a relatively braided metal cable orthe like that is sized to extend into the slots 124,126. In thisembodiment, the length of the flexible member 140 may be determined inthe manner described above. The apparatus 110 may be secured to the treeportion T as follows. The hanger member 130 is placed on a front side ofthe tree and the first and second ends 142, 144 of the flexible member140 are brought around the backside of the tree portion T as shown. Withthe spring clamps 129 removed or loosened from the mounting member 120,one portion 141 of the flexible member 140 is inserted through one ofthe spring clamps 129 and into the first elongated slot 124 such thatthe first end 142 protrudes out of the right end 123 of the body portion122. The other portion 143 of the flexible member 140 is insertedthrough the other spring clamp 129 and into the second slot 124 suchthat the second end 124 thereof extends out of the left end 125 of thebody portion 122. Thereafter the clamps 129 are installed on themounting member 120 as shown in FIG. 14. The spring clamps 129 serve toclamp the body portion 122 into sliding frictional engagement with theportions 141, 143 of the flexible member 140 extending therethrough. Inone embodiment, it is desirable for equal amounts of flexible member 140to protrude out from each end 123,125 of the mounting member 120. Inanother embodiment, a slug or stop is attached to one end of theflexible member 140 and that end may be pulled tight to the body portionof the mounting member such that only one portion of the flexible member140 slides through the mounting member. In other embodiments, only oneslot is provided in the mounting member 120. In this embodiment, one endof the flexible member 140 is non-movably attached to one end or portionof the mounting member 120. The flexible member 140 is looped around thetree in the above described manner and inserted into the slot in themounting member 120. After the flexible member 140 has been insertedinto the slot such that the second end protrudes out from one side ofthe mounting member 120, the user secures the spring clamps 129 in theabove-described manner. In at least one embodiment, the spring clamps129 are substantially identical. In other embodiments, the spring clamps129 may be of different strengths such that the user may obtain adesired amount of frictional resistance between the flexible member 140and the support member 120.

FIG. 16 illustrates an alternative embodiment 110′ that employs arotatable compression sleeve 160 instead of the spring clamps 129 tocompress the retainer body 120′ into sliding frictional engagement withthe flexible member 140. As can be seen in FIG. 16, the user aligns theslot 162 in the compression sleeve 160 with the first slot 124 in themounting member 120′ and inserts the portion 141 of the flexible member140 therein. Thereafter, the user rotates the compression sleeve 160 tobring the slot 162 into alignment with the slot 126 in the mountingmember 120′ and inserts the portion 143 of the flexible member 140therein. The user again rotates the compression sleeve 160 so that theslot 162 therein is not aligned with either slot 124, 126 in themounting member 120′. The embodiments described above may be installedon trees without the use of hand tools. In alternative embodiments,however, screws or bolts may be employed in place of, or in addition to,the spring clamps and compression sleeve to close the slots onto theflexible member portions a sufficient amount so as to attain a desiredamount of sliding frictional fit between the mounting member 120 and theflexible member 140.

In alternative embodiments, the hanger 130 may be omitted. In thoseembodiments, the object 12 may be attached directly to the mountingmember 120. For example, the mounting member 120 may be formed with aflat surface thereon to facilitate easy attachment of a sign theretowith, for example, double-sided tape or adhesive. In still otherimplementations, the sign may be attached directly to the mountingmember 120 with self tapping screws or similar fastener arrangements. Inyet other arrangements, the sign or other object may be suspended fromthe flexible member with clamps, hooks, etc. In alternativeimplementations, for example, the mounting member may have a hangermember 30 or 130 attached directly thereto or formed therewith. In stillother embodiments, the mounting member 120, 120′ may be integrallyformed with the object itself. In such embodiments, no separate mountingmember or hanger member is employed.

In still another alternative embodiment, for example, the mountingmember may comprise a piece of flexible tube, conduit or hose that maybe made from, for example, a polymer material. The first and second endsof the flexible member may be inserted through the mounting member sothat they protrude in opposite directions out of each end of themounting member. For example, if the mounting member comprises a pieceof rubber tube or hose, after the flexible member has been wrappedaround a portion of the tree, the user feeds the first end of theflexible member through the rubber tube until it protrudes out throughthe other end of the tube. The user then feeds the second end throughthe tube in the opposite direction. Once the user has fed the second endout through the tube, the first and second ends of the flexible memberare pulled in opposing directions to cinch the apparatus to the treeportion. Any of the various objects described herein may be attached toor suspended from the mounting member using any of the various hangermember embodiments and fastener arrangements disclosed herein. Themounting member is sized relative to the flexible member such that whenthe flexible member is wrapped around a portion of the growing tree asdescribed above, a sufficient amount of friction is generated betweenthe flexible member and the mounting member so as to enable the flexiblemember to be cinched to the tree portion at a desired height. As thetree portion expands from tree growth, the portions of the flexiblemember contained within the mounting member will frictionally slide inopposite directions to accommodate the expansion while remaining cinchedto the tree portion. This process will continue until the first andsecond ends of the flexible member pull out of the mounting memberresulting from expansion of the tree portion at which point theapparatus and object will simply fall from the tree.

FIGS. 17 and 18 illustrate another apparatus 210 for supporting anobject such as a sign from a tree portion T. This embodiment employs amounting member 220, a hanger member 130 and a flexible member 240. Ascan be seen in FIG. 18, the mounting member 220 comprises a body portion222 and an attachment portion 260. In at least one form, the attachmentportion 260 has a planar flange 262 that has a slot 264 extendinginwardly from one edge thereof. The slot 264 may terminate in acentrally-disposed hole 266 in the flange 264. In alternativeembodiments, the hole 266 could conceivably be omitted. Formed orotherwise attached to the underside of the flange 264 is a C-shapedcollar portion 268 that is sized to extend into a tapered hole portion224 in the body portion 222. In addition, at least one, and preferablyat least two, retainer lugs 272 are formed on the collar portion 268that are oriented to retainingly engage an annular ledge 226 formed inthe body portion 222.

In various embodiments, the body portion 222 and the attachment portion260 may be fabricated from similar polymer or rubber materials. Inalternative embodiments, the body portion 222 may be fabricated frommetal and the attachment portion fabricated from polymer, rubber ormetal. Also in various embodiments, the flexible member 240 may comprisea braided metal cable or similar member and have a first end 242attached to a body portion 222 of the mounting member 220. The flexiblemember 140 may be affixed to the hanger member 130 by inserting itthrough holes 133 in the channel portion 132 thereof as illustrated inFIG. 17. The sign may be attached to the attachment face portions 134 inany of the various manners described herein. In an alternativeembodiment, the body portion 222 is integrally formed with the object,but may otherwise operate in the manner described herein.

The apparatus 210 may be attached to the tree portion T as follows. Theuser locates the apparatus 210 at a desired height on the tree andlocates the mounting member 220 on the backside of the tree portion. Asused herein, the term “backside of the tree” generally refers to theside of the tree portion T that is opposite to the side of the tree fromwhich the hanger member and object will be suspended from (i.e., the“front side”). The user then inserts the second end 144 of the flexiblemember 140 through the hole 224 in the body portion 222 of the mountingmember 220. While supporting the body portion 222 adjacent the backsideof the tree, the user inserts the portion 143 of the flexible member 140into the slot 264 in the attachment portion 260. Thereafter, theC-shaped collar portion 268 is inserted into the tapered hole 224 in thebody portion 222 of the mounting member 220. As the C-shaped collarportion 268 is pushed into the tapered hole 224, the C-shaped collar 268urges the slot 264 to close around the portion 143 of the flexiblemember 140. The collar 268 is pressed into the body portion until thelugs 272 retainingly engage the ledge 226 in the body portion 222 toaffix the attachment portion 260 thereto. The slot 264 is sized relativeto the flexible member 240 such that when the attachment portion 260 isattached to the body portion 220 as described above, a desired amount ofsliding frictional fit is established between the flexible member 240and the attachment portion 220. The user may then grasp the mountingmember 220 while pulling on the second end 144 of the flexible member240 to cinch or otherwise secure the flexible member 240 tight to thetree. As the tree continues to grow, the flexible member 240 continuesto frictionally slip through the slot 264 to accommodate such growthuntil eventually all of the flexible member 240 pulls through the slot264 (without any human intervention), at which point the apparatus mayfall from the tree.

FIG. 19 illustrates an alternative mounting member 320 and flexiblemember 340. In this embodiment, the flexible member 340 comprises a ballchain that may be fabricated from metal. It is conceivable, however,that the flexible member 340 could also be molded from a polymermaterial. Both configurations have a series of spaced retainer balls344. The flexible member 340 may be used in connection with a hangermember 130 in the manner described above or the mounting member 320 maybe integrally formed with a hanger member. In still other embodiments,the mounting member 320 is integrally formed in the object itself. Thus,for those embodiments, no hanger member or separate support member isotherwise required.

After being attached to the hanger member 130, the user loops the endsof the flexible member 340 around the tree. In at least one embodiment,a first end 342 of the flexible member 340 is engaged with a first endor portion 322 of a mounting member 320. As shown in FIG. 15, a keyholeslot 326 is provided in the first end 322 to enable to the user to lockthe first end 342 of the flexible member 340 therein. The remainingportion 343 of the flexible member 340 is inserted through a taperedslot 328 in a second end or portion 324 of the mounting member 320. Thetapered slot 328 is sized relative to the balls 344 to enable the balls344 to slip therethrough when a sufficient tensile force is appliedthereto to accommodate growth of the tree. As the tree portion Tcontinues to grow, the flexible member 340 can continue to slip throughthe mounting member 320 to accommodate such growth until eventually allof the flexible member 340 pulls through the tapered slot 328. As such,the apparatus may fall from the tree or the original flexible member bereplaced with a longer flexible member to accommodate further treegrowth.

FIG. 20 illustrates an alternative mounting member 420 and flexiblemember 440. In this embodiment, the flexible member 440 comprises aflexible strap member that has serrations 444 formed in one sidethereof. The flexible member 440 may be fabricated from metal, polymer,rubber, etc. The mounting member 420 may be used in connection with ahanger member 130 in the manner described above. In still otherembodiments, the mounting member 420 is integrally formed in the objectitself. Thus, for those embodiments, no hanger member or separatesupport member is otherwise required.

A first end 442 of the flexible member 440 is attached to a mountingmember 420. For example, the first end 442 of the flexible member 440may be attached to a first end 422 of the mounting member 420 by a rivet423 or other fastener. The mounting member 420 further includes a secondend 424 that has an adjustable frictional tab 426 that is configured tofrictionally engage the serrations 444 on the flexible member 440. Anadjustment screw 428 is mounted to the mounting member 420 to initiallyadjust the amount of frictional contact between the frictional tab 426and the serrations 444. After the first end is attached to the hangermember 130, the user loops the free end 446 of the flexible member 440around the tree and inserts it through the mounting member 420 as shown.The user then locates the hanger member at a desired position around thetree portion and cinches the flexible member 440 tight therearound bypulling the end 446 therethrough and adjusting the screw 428 to achievea desired amount of frictional engagement between the frictional tab 426and the serrations 444 on the flexible member 440. As the diameter ofthe tree portion increases, the flexible member 440 is permitted to sliprelative to the mounting member 420 while the frictional tab 426continues to apply friction to the flexible member 440 to maintain itcinched around the tree. This process will automatically continue untilthe tree portion has expanded to a point wherein the flexible member 440disengages the frictional tab 426 and the apparatus is permitted to fallfrom the tree.

FIG. 21 illustrates another mounting member 520 and flexible member 540.In this embodiment, the flexible member 540 comprises a flexible strapmember that has serrations 544 formed in one side thereof. The flexiblemember 540 may be fabricated from metal, polymer, rubber, etc. material.The mounting member 520 may be used in connection with a hanger member130 in the manner described above. In still other embodiments, themounting member 520 is integrally formed in the object itself. Thus, forthose embodiments, no hanger member or separate support member isotherwise required.

A first end or portion 542 of the flexible member 540 is attached to amounting member 520. For example, the first end 542 of the flexiblemember 540 may be attached to a first end 522 of the mounting member 520by a rivet 523 or other fastener. The mounting member 520 furtherincludes a second end or portion 524 that has a molded spring arm 526that is configured to frictionally engage the serrations 544 on theflexible member 540. After the first end is attached to the hangermember 130, the user loops the free end 546 of the flexible member 540around the tree and inserts it through the mounting member 520 as shown.The user then locates the hanger member 130 at a desired position aroundthe tree and cinches the flexible member 540 tight therearound bypulling the end 546. As the diameter of the tree portion increases, theflexible member 540 is permitted to frictionally slip relative to themounting member 520. This process will automatically (i.e., withoutfurther human intervention or adjustment) continue until the treeportion has expanded to a point wherein the flexible member 540disengages the spring arm 526 and the apparatus is permitted to fallfrom the tree.

FIGS. 22 and 23 illustrate another mounting member 620 and flexiblemember 640. In this embodiment, the flexible member 640 comprises aflexible strap member that has a first end 642 and a second end 644. Inone embodiment a portion of the flexible member 640 has a first segment646 of first serrations 648 formed on one side thereof and a secondsegment 650 of second serrations 652 formed on the other side thereof.In one embodiment, the first and second segments 646, 650 may extendfrom a central portion of the flexible member 640 or the first segment646 may, for example, be considerably shorter than the second segment650 which may extend from the first segment 646 to the second end 644 ofthe flexible member (on the opposite side thereof).

As can be further seen in FIGS. 22 and 23, the mounting member 620 isformed with a first wall 622, a central wall 624 and a second wall 626.The first wall 622 and central wall 624 serve to define a first passage628 therethrough that is configured to receive the portion of theflexible strap member 640 that has the first segment 646 of firstserrations 648 thereon. In addition, the first wall 622 has a firstfrictional tab 660 formed therein that is shaped to frictionally engagethe first serrations 648. Similarly, the second wall 626 and the centralwall 624 serve to define a second passage 662 therethrough that isconfigured to receive the portion of the flexible strap member 640 thathas the second segment 650 of second serrations 652 thereon. The secondwall 626 has a second frictional tab 670 formed therein that is shapedto frictionally engage the second serrations 652.

The mounting member 620 and flexible member 640 may be used as follows.In the embodiment wherein the first segment 646 of serrations is shorterthan the second segment 650, the user first inserts the first end 642 ofthe flexible member 640 in the first passage 628 (arrow 680 in FIG. 23)until the serrations 648 frictionally engage the first friction tab 660.Thereafter, the second end 644 of the flexible member 640 is insertedinto the second passage 662 in the mounting member 620 (arrow 682 inFIG. 23). As the second end 644 of the flexible member 640 is pushedthrough the second passage 662 of the mounting member 620, the secondfriction tab 670 flexes to permit the flexible member 620 to passtherethrough sufficiently far enough to enable the apparatus to becinched to the tree portion. The user orients the mounting member 620such that the first wall portion 622 and, more particularly, the firstfriction tab 660 abuts the tree portion. The user continues to pull theflexible member 640 (in direction 682) to cinch or secure the apparatusto the tree portion. Because the first friction tab 660 is abuttedagainst the tree portion, the first friction tab 660 is prevented fromotherwise releasing the corresponding first serration 648. As the treegrows, the portion of the flexible member 640 that has the secondsegment 650 of second serrations 652 thereon will be pulled out of themounting member 620 in direction 684 (FIG. 22) to accommodate the growthwhile still remaining cinched to the tree portion without the need forhuman intervention. This process will automatically continue until thetree portion has expanded to a point wherein the flexible member 640disengages the mounting member 620 and the apparatus is permitted tofall from the tree.

The flexible member 640 may be fabricated from metal, polymer, rubber,etc. material. The mounting member 620 may be used in connection with ahanger member 130 in the manner described above. In still otherembodiments, the mounting member 620 is integrally formed into theobject itself. Thus, for those embodiments, no hanger member or separatesupport member is otherwise required.

In an alternative embodiment wherein the first segment 646 of serrations648 is substantially as long as the second segment 650 of serrations652, the first end 642 of the flexible member 640 and the second end 644of the flexible member are inserted through passages 628, 662,respectively and are pulled through the mounting member 620 in oppositedirections such that when the apparatus is cinched to the tree portion,the distance that the portion of the flexible member 640 having thefirst segment 646 thereon protrudes out from the mounting member 620 issubstantially equal to the distance that the portion of the flexiblemember 640 that has the second segment 650 of serrations thereonprotrudes out from the mounting member 620. In this case however, themounting member 620 can be oriented such that when cinched around thetree, neither of the friction arms 660, 670 abut the tree portion. Asthe diameter of the tree portion increases, the flexible member 640 ispermitted to slip in opposite directions relative to the mounting member620 to accommodate the growth while still remaining cinched to the treeportion without the need for human intervention. This process willautomatically continue until the tree portion has expanded to a pointwherein the flexible member 640 disengages the mounting member 620 andthe apparatus is permitted to fall from the tree.

FIGS. 24 and 25 illustrate another apparatus 710 that may employ ahanger member 130 of the type and construction described above tosuspend a sign 12 from a tree portion T. This embodiment employs atleast one, and preferably at least three, mounting members 720 and aflexible member 740. In various embodiments, the flexible member 740 maycomprise a braided metal cable, a solid cable or wire, etc. In at leastone form, each of the mounting members 720 comprises a metal plate thathas two sets 722, 724 of spaced holes 726 therein. The holes 726 aresized to facilitate passage of the flexible member 740 therethrough. Inat least one embodiment, the flexible member 740 is woven through theholes 726 in the mounting members 720 as shown in FIGS. 24 and 25. Inparticular, the flexible member 740 is woven through the first set 722of holes 726 and also through the second set 724 of holes 726 in one ofthe mounting members 720 (designated as 720A in FIGS. 24 and 25). Theflexible member 740 is only passed through the outermost two holes 726in the other two mounting members 720 (designated as 720B and 720C). Itwill be understood that the mounting members 720B and 720C serve toprevent the flexible member 740 from contacting the tree at thoselocations and that the retainer 720A serves to facilitate frictionalengagement with the flexible member 740. In particular, the amount ofsliding frictional engagement attained between the flexible member 740and the mounting member 720A may be dependent upon the distance betweenthe holes 726 in each pair of holes 722, 724 (designated as distance “D”in FIG. 24). The mounting members 720B, 720C may be replaced with thebumper members 80 and/or 90 as was described above. As the diameter ofthe tree portion increases, the flexible member 740 is permitted to slipin opposite directions relative to the mounting member 720A toaccommodate the growth while still remaining cinched to the tree portionwithout the need for human intervention. This process will automaticallycontinue until the tree portion has expanded to a point wherein theflexible member 740 disengages the mounting member 720 and the apparatusis permitted to fall from the tree.

FIGS. 26 and 27 illustrate another apparatus 810 that may employ ahanger member 130 of the type and construction described above tosuspend a sign from a tree portion T. This embodiment employs a flexiblemember 840 that comprises a strap that may be fabricated from, forexample, metal, polymer, fiberglass, etc. that has a first end 842 and asecond end 844. The strap 840 is substantially centered on the hangermember 130 such that a first portion 843 of the strap 840 that extendsaround one portion of the tree is essentially the same length as thesecond portion 845 that extends around another portion of the treeportion T. The strap extends through strap openings 135 in the hangermember 130. The strap 840 is wrapped around the backside of the treeportion as shown in FIG. 27 and at least one, and preferably three,retainer clips 850 are applied to the strap 840. Each clip 850essentially wraps around the overlapping strap portions 843, 845, but isnot tightly crimped thereto. However, in at least one embodiment, atleast one and, preferably all, of the clips 850 apply an amount offriction to the flexible member 840 to retain the flexible member 840cinched around the tree portion as the tree portion continues to expand.Thus, the clips 850 serve to slidably support the overlapping portions843, 845 therein. As the diameter of the tree portion increases, thestrap portions 843, 845 move in opposite directions within the clips 850to accommodate the growth while still remaining cinched to the treeportion without the need for human intervention. This process willautomatically continue until the tree has expanded to a point whereinthe flexible member 840 disengages the clips 850 and the apparatus ispermitted to fall from the tree.

In alternative embodiments, the flexible member 840 may be integrallyformed with the object an otherwise function in the manner describedabove. Thus, for those embodiments, no hanger member is otherwiserequired.

FIGS. 28 and 29 illustrate another apparatus 910 that may employ ahanger member 130 of the type and construction described above tosuspend a sign from a tree portion. This embodiment employs amulti-segment flexible member 940 that comprises a first strap portion950 that is fabricated from metal material and that has a first end 952and a second end 954. The first strap portion 950 is substantiallycentered on the hanger member 130 and may be attached thereto by screws,bolts, rivets, adhesive, etc. A second strap portion 960 is configuredto be attached to the first end 952 of the first strap portion 950 andslidably attached to the second end 954 of the first strap portion 950to span therebetween. In one embodiment, the second strap portion 960may be configured to be attached to the first strap portion 950 at aplurality of predetermined positions. For example, as can be mostparticularly seen in FIG. 29, a first end 962 of the second strapportion 960 may have a hook formed therein that is adapted to engageanyone of a plurality of latch slots 956 formed in the first strap 950.A second end 964 of the second strap portion 960 is sized to slidablyextend through at least one and preferably at least two retainer clips958 formed in the first strap portion 950 as shown. The clips 958 aresized relative to the second end 964 of the second strap 960 to permitit to slide relative thereto.

The apparatus 910 is affixed to the tree by wrapping the first strap 950around the backside of the tree. The user then hooks the second strap960 to the first strap 950 by hooking the first end 962 of the secondstrap portion 960 into the appropriate slot 956 in the first strapportion 950. The user then slides the second end 964 of the second strapportion 960 through the clips 958 in the first strap portion. In oneembodiment, the clips 958 are sized to permit the second end 964 of thesecond strap portion 960 to slide therethrough while applying an amountof friction thereto to enable the flexible member assembly 950 to remaincinched around the tree portion at the desired height above the groundas the tree portion continues to expand. As the diameter of the treeportion increases, the second strap portion 960 slides through the clips958 to accommodate the growth while still remaining cinched to the treeportion without the need for human intervention. In an alternativeembodiment, the second strap portion may be movably attached to thefirst end of the first strap portion by a set screw or otherarrangement. In yet another alternative embodiment, the second strapportion is integrally formed with the first strap portion and protrudesout from a first end therefrom to be slidably received within theclip(s) in the second end thereof.

In alternative embodiments, portions of the flexible member assembly 950may be integrally formed with the object an otherwise function in themanner described above. Thus, for those embodiments, no hanger member isotherwise required.

FIGS. 30 and 31 illustrate another apparatus 1010 that includes a hangerplate 1030 to which a sign or other object may be attached by screws,bolts, rivets, clamps, adhesive, double-sided tape, paper fastenerbrads, etc. Other embodiments may employ a hanger member 130 of the typeand construction described above. This embodiment employs a flexiblemember 1040 that comprises a metal strap that has at least one, andpreferably a plurality of, crimps 1046 therein. The strap 1040 has afirst end 1042 that has a hook formed therein that is adapted to engageany one of a plurality of latch slots 1049 formed in a second end 1044of the strap 1040. The apparatus 1010 is affixed to the tree portion bywrapping the first strap 1040 around the backside of the tree. The userthen hooks the first end 1042 into an appropriate slot 1048 to cinch thestrap 1040 around the tree portion. As the diameter of the tree portionincreases, the crimps 1046 in the strap 1040 permit the flexible member1040 to expand, or straighten, to, essentially relieve tension andaccommodate a certain amount of tree growth without the need for humanintervention. However, once the tree portion has attained a diameterthat has resulted in the maximum expansion of the flexible member 1040,the user may release the apparatus from the tree portion and reconnectthe first end 1042 in another slot 1048 to lengthen the flexible member1040 to accommodate additional growth.

In alternative embodiments, the flexible member assembly 1040 may beintegrally formed with the object an otherwise function in the mannerdescribed above. Thus, for those embodiments, no hanger plates or hangermembers are otherwise required.

FIG. 32 illustrates an alternative apparatus 1010′ wherein a first end1042′ of a flexible strap 1040′ is attached to a second end portion1044′ of the flexible strap 1040′ by a screw arrangement 1050. In oneembodiment, the screw arrangement 1050 may comprise a threaded stud 1052that is affixed to the first end 1042′ of the strap 1040′ and a wingstop 1054. A series of holes 1048′ or a slot are provided in the secondend portion 1044′ of the strap 1040′ to provide the user with theability to select the appropriate hole required to cinch the strap 1040′to the tree. As with the above-described embodiment, the crimps 1046enable the flexible member 1040′ to accommodate a certain amount of treegrowth without human intervention. Once the tree has attained a diameterthat has resulted in the maximum expansion of the flexible member 1040′,the user may release the apparatus from the tree and insert the threadedstud 1052 into another hole 1048′ to lengthen the flexible member 1040′to accommodate additional tree growth.

In alternative embodiments, the flexible member assembly 1040′ may beintegrally formed with the object an otherwise function in the mannerdescribed above. Thus, for those embodiments, no hanger plates or hangermembers are otherwise required.

FIGS. 33 and 34 illustrate another apparatus 1110 that, in at least oneform, includes a hanger member 130 of the type and constructiondescribed above. This embodiment employs a flexible member 1140 thatcomprises a strap that has a first end 1142 and a second end 1144. Afirst spring tab 1143 is formed on the first end of the flexible member1142. The flexible member 1140 also has a longitudinal slot 1146 thereinto facilitate movable attachment of a second spring tab 1150 thereto by,for example, a wing nut and set screw assembly 1152. To install theapparatus 1110 on a tree, the user wraps the flexible member 1140 aroundthe backside of the tree portion T as shown in FIG. 34. A coil spring1160 is attached between the first and second spring tabs 1143, 1150.The user then tightens the set screw assembly 1152 in position withinthe slot 1146. It will be understood that the spring 1160 serves toretain the strap 1140 in cinching engagement around the tree and willstretch to accommodate a certain amount of tree growth. However, in thisembodiment, the user will have to periodically monitor the tree growthand adjust the position of the second spring tab 1150 accordingly toprevent the spring 1160 from becoming overstretched.

In alternative embodiments, the flexible member assembly 1140 may beintegrally formed with the object an otherwise function in the mannerdescribed above. Thus, for those embodiments, no hanger plates or hangermembers are otherwise required.

FIGS. 35 and 36 illustrate another apparatus 1110′ that, in at least oneform, includes a hanger member 130 of the type and constructiondescribed above. This embodiment employs a flexible member 1140′ thatcomprises a strap that has a first end 1142′ and a second end 1144′. Aspring tab 1143′ is provided on the first end 1142′ of the flexiblemember 1140′. To install the apparatus 1110′ on a tree, the user wrapsthe flexible member 1140′ around the backside of the tree portion T asshown in FIG. 36. A coil spring 1160′ is attached between a portion ofthe flexible member 1140′ and the spring tab 1143′ as shown to cinch theflexible member 1140′ to the tree portion. As the tree grows, the spring1160′ will stretch. The spring will accommodate tree growth until thespring 1160′ is essentially completely elongated.

In alternative embodiments, the flexible member assembly 1140′ may beintegrally formed with the object an otherwise function in the mannerdescribed above. Thus, for those embodiments, no hanger plates or hangermembers are otherwise required.

FIG. 37 illustrates an apparatus 1210 configured to hang or secure anobject 12 to a tree portion T at a desired height or elevation above theground. In this embodiment, the apparatus 1210 includes an elongatedmounting member 1220 that has a first end or portion 1222 and a secondend or portion 1224. The elongated mounting member 1220 may befabricated from, for example, aluminum, steel or other metals or frompolymer materials. The object (in the illustrated case, a sign 12) maybe attached to the mounting member 1220 by, for example, self tappingscrews 1221. However, the sign may be attached to the mounting member1220 by double-sided tape, adhesive, bolts, clips, clamps, paperfastener brads, etc.

In various embodiments, the apparatus 1210 further includes a flexiblemember 40 that has a first end 42 and a second end 44. In at least oneembodiment, the flexible member 40 comprises a relatively braided metalcable. It is conceivable, however, that the flexible member 40 maycomprise other forms of cable or wire fabricated from a variety ofmaterials. The flexible member 40 may also comprise a solid wire orsimilar arrangement fabricated from metal or polymer material. Invarious arrangements, the flexible member 40 has a length that isgreater than an expected circumference of the tree portion to which itis to be attached at the end of a predetermined or expected period oftime.

In the illustrated embodiment, the first end 42 of the flexible member40 is attached or affixed to a first end or portion 1222 of the mountingmember 1220. In at least one embodiment, wherein the flexible member 40comprises braided cable, the first end 42 of the flexible member 40 mayextend through a hole 1223 in the first end 1222 of the mounting member1220 and have a lug or stop 46 attached thereto to prevent the flexiblemember 40 from pulling through the hole 1223. The lug 46 may befabricated from, for example, aluminum or other metal material and beconfigured to be non-movably crimped onto or otherwise affixed to thefirst end of the cable 40 in the field by the user or by themanufacturer. It will be understood that other methods of securing orfastening the first end 42 of the flexible member 40 to the first end1222 of the mounting member 1220 may be employed. For example, the firstend 42 of the flexible member 40 may be permanently attached to thefirst end 1222 of the mounting member 1220 by welding or other suitablefastener arrangements. In still other embodiments, the flexible member40 may be clamped or glued to the first end 1222 of the mounting member1220. In still other embodiments, the first end 42 of the flexiblemember 40 may be attached or secured to the first end or portion 1222 ofthe mounting member 1220 by the slot arrangement described above. In yetanother embodiment wherein the mounting member comprises the objectitself (or stated another way, no mounting member is employed), thefirst end of the flexible member 40 may be attached to a first portionof the object using any of the arrangements disclosed herein.

As can be seen in FIG. 37, the flexible member 40 is extended around thebackside of the tree portion T, and a second end 44 of the flexiblemember 40 is passed through the hole or opening 25 in the second end orportion 1224 of the mounting member 1220 which may be positionedadjacent the front side of the tree portion T. The hole 1225 may besized relative to the flexible member 40 such that it may freely passtherethrough. Thereafter, the user installs a friction generatingferrule or slug 1250 on the second portion of the flexible cable 40 thatprotrudes out through the hole 25. In at least one embodiment, theferrule 1250 may be fabricated from aluminum or other metal material andhave a bore 1252 therethrough that is sized to receive the flexiblemember 40 (in the illustrated embodiment, a cable) therethrough. Theuser may then slide the ferrule 1250 into abutting relationship with themounting member 1220 as shown in FIG. 37 to cinch the flexible member 40to the tree portion. The ferrule 1250 is sized and shaped (i.e.,“configured”) relative to the hole 1225 in the mounting member 1220 suchthat the ferrule 1250 is prevented from passing therethrough. The usermay crimp or otherwise fasten the ferrule 1250 to the cable 40 such thatthe apparatus 1210 is cinched to the tree portion at the desired height,yet is movable thereon to accommodate tree growth (expansion of the treeportion).

The ferrule 1250 may be crimped using crimping or a swaging tool suchthat when the ferrule has been crimped onto the cable 40, a desiredamount of sliding frictional fit is established between the ferrule 1250and the cable 40. Such sliding frictional fit is sufficient to retainthe apparatus 1210 cinched to the tree portion T at the desired heightabove the ground, yet will permit the ferrule to slide down the cable 40in the “E” direction as the tree portion T grows and expands. See FIG.38. Such sliding frictional fit may for example, also have a magnitudethat enables the user to slide the ferrule 1250 along the cable 40manually without the aide of tools. The swaging tool may be configuredwith a stop feature, for example, such that when the user fullycompresses or squeezes the tool around the ferrule, the ferrule 1250 iscompressed onto the cable sufficiently to establish the desired slidingfrictional fit and any over-compression of the ferrule 1250 isprevented.

Other ferrule or friction generating configurations are contemplated. Asindicated above, the ferrule 1250 may be fabricated from aluminum ormetal. In other embodiments, the ferrule is manufactured from a polymeror rubber material. In still other embodiments, the ferrule is equippedwith a set screw that may be screwed into contact with the cable toestablish the desired amount of sliding frictional fit therebetween.Other ferrule embodiments may include a knockout or detent portion thatmay be squeezed or compressed into frictional contact with the cable.Other forms of ferrule constructions may comprise a metal body portionthat contains a polymer sleeve that can be compressed into the cable toestablish the desired sliding frictional fit. Ferrules may also bereferred to herein as “friction generating members”.

In various embodiments, the ferrule(s) are sized and configured relativeto the cable such that when the ferrule is secured to the cable, at easta minimal amount of sliding frictional fit will still occur. As usedherein, the term “minimal amount of sliding frictional fit” refers tothe minimal amount of fit established between the ferrule and cable thatis required to cinch or otherwise secure the apparatus to the treeportion at the desired elevation above the ground as the tree continuesto grow. Thus, the minimal amount of sliding frictional fit required tosecure an apparatus and object having a first total weight may be largerthan the sliding frictional fit required to secure another apparatus andobject that has a second total weight that is less than the first totalweight.

In those applications wherein significant swings in temperature mayoccur which could result in expansion and contraction of the variouscomponents, it may be desirable for the ferrules or latch mechanismcomponents to be fabricated from material that has the same coefficientof thermal expansion as the material comprising the flexible member. Insuch embodiments, the ferrule(s) or latch(es) will expand and contractat substantially the same rate as the flexible member such that adesired amount of sliding frictional contact is maintained therebetweenduring such fluctuations in temperature. In other embodiments whereinthe ferrule(s) or latch(es) and cable are manufactured from dissimilarmaterials, the ferrule(s) may be sized and configured relative to thecable such that when the ferrule (or latch(es)) is secured to the cable,at east the minimal amount of sliding frictional fit will still occurand yet the ferrule(s) will remain frictionally slidable on the cable(or the cable will remain frictionally slidable through the latch(es))in response to the radial forces applied thereto as the tree portionexpands regardless of the temperature.

After the apparatus 1210 has been attached to the tree portion T, as thetree portion T continues to grow, the ferrule 1250 will frictionallymove or slide on the cable 40 away from the support member 1220 toaccommodate such growth without any need for human intervention. Whenthe circumference of the tree portion T exceeds the aggregate length ofthe flexible member 40 and the support member 1220, the apparatus 1210will fall from the tree portion To prevent any inadvertent damagethereto as the tree continues to grow. The apparatus may be reused on asmaller tree or the user may replace the original flexible member with alonger flexible member and reattach it to the tree in theabove-described manner.

As described above, the aforementioned arrangement may also be used toattach an object 12 to a tree portion T without the use of a mountingmember. In such arrangement, the first end 42 of the flexible member 40is secured or attached to a first portion of the object 12. With theobject 12 adjacent the front side of the tree portion T, the flexiblemember 40 is passed around the backside of the tree portion T andinserted through a hole in another portion of the object 12. The usermay then slide the ferrule or ferrules 1250 onto the portion of theflexible member protruding through the opening to cinch the object tothe tree portion T in the above-described manner.

In an alternative embodiment, the first end 42 is not non-movablyattached to the first end 1222 of the mounting member 1220. In at leastone embodiment, for example, the first end 42 of the flexible member 40movably extends through the hole 1223 in the support member 1220. Thefirst end 42 extends through the hole 1223 a distance that issubstantially equal to a distance that the second end 44 extends throughthe hole 1225. A second ferrule 1250 is slid onto and attached to theportion of the flexible member 40 extending through hole 1223 andbrought into abutting engagement with the support member 1220 and iscrimped or otherwise attached to the flexible member as described above.As the tree expands, both of the ferrules 1250 may frictionally move onthe flexible member 40 to accommodate the expansion as was describedabove. In still other arrangements, the holes 1223, 1225 may be providedthrough portions of the object 12 such that no additional mountingmember is employed. For those embodiments wherein a separate mountingmember is employed, the sign or object 12 may be directly attached tothe mounting member by means of any of the attachment arrangementsdescribed herein. In alternative embodiments, any of the various hangermembers disclosed herein may also be employed. However, in otherembodiments, the mounting member may comprise at least a portion of theobject itself.

FIG. 39 illustrates another apparatus 1310 configured to hang or suspendan object 12 on a tree portion T at a desired height above the ground.In this embodiment, the apparatus 1310 includes an elongated mountingmember 1320 that may be similar in shape to the hanger 130 describedabove. For example, in one embodiment, the support member 1320 maycomprise a hat channel that is fabricated from steel or other metal orpolymer material. The support member 1320 has a channel 1322 and tworaised planar attachment faces 1324. Double-sided tape may be applied toeach attachment face 1324 to facilitate easy attachment of a sign 12 orother object thereto. In other embodiments, the sign may be attached tothe support member 1320 by self tapping screws 1325 or clamps, rivets,screws, bolts, clips, adhesive, paper fastener brads, etc.

In various embodiments, the apparatus 1310 further includes a flexiblemember 40 that has a first end 42 and a second end 44. In at least oneembodiment, the flexible member 40 comprises a relatively braided metalcable. It is conceivable, however, that the flexible member 40 maycomprise other forms of cable or wire fabricated from a variety ofmaterials. It is further anticipated that, for at least someembodiments, the flexible member 40 may comprise a strap fabricated fromcloth or fiber or metal or polymer or various combinations of suchmaterials. The flexible member 40 may also comprise a solid wire orsimilar arrangement fabricated from metal or polymer. The flexiblemember may have a length that is greater than an expected circumferenceof the tree portion to which it is to be attached at the end of anexpected or predetermined time period.

In the illustrated embodiment, the first end 42 of the flexible member40 is attached or affixed to the mounting member 1320. In at least oneembodiment, wherein the flexible member 40 comprises cable, the firstend of the flexible member 40 extends through a hole or opening 1326 inthe mounting member 1220 and has a lug or stop 46 attached thereto toprevent the flexible member 40 from pulling through the hole 1326. Thelug 46 may be fabricated from, for example, aluminum or other metalmaterial and be configured to be non-movably crimped onto or otherwiseaffixed to the first end 42 of the cable 40 in the field or by themanufacturer. It will be understood that other methods of fastening thefirst end 42 of the flexible member 40 to the mounting member 1320 maybe employed. For example, the first end 42 of the flexible member 40 maybe permanently attached to the mounting member 1320 by welding or othersuitable fastener arrangements. In still other embodiments, the flexiblemember 40 may be clamped or glued to the mounting member 1320.

As can be seen in FIG. 39, a second end 44 of the flexible member 40 ispassed around the backside of the tree portion T and inserted through asecond hole 1327 in the mounting member 1320. The hole 1327 is sizedrelative to the flexible member 40 such that it may freely passtherethrough. The second end 44 of the flexible member 40 is passedthrough a third hole 1328 in the mounting member 1320. Thereafter, theuser installs a ferrule or slug 1250 thereon in the manner describedabove. The ferrule 1250 is sized and shaped relative to the hole 1328 inthe mounting member 1320 such that the ferrule 1250 is prevent frompassing therethrough. The user may then crimp or otherwise fasten theferrule 1250 to the cable 40 (as described above to attain a desiredamount of sliding frictional fit) such that the apparatus 1310 iscinched to the tree portion at the desired height.

After the apparatus 1310 has been attached to the tree portion, as thetree portion continues to grow, the ferrule 1250 will frictionally slideon the cable 40 away from the support member 1320 to accommodate suchgrowth (expansion) without any need for human intervention oradjustment. When the circumference of the tree portion T exceeds thelength of the flexible member 40 and the support member 1320, theapparatus 1310 may fall from the tree portion T to prevent anyinadvertent damage thereto as the tree continues to grow. The apparatusmay be reused on a smaller tree or the user may replace the originalflexible member with a longer flexible member and reattach it to thetree portion T to accommodate further growth.

FIGS. 40-46 and 52 illustrate another apparatus 1410 for supporting anobject such as a sign from a tree portion T at a desired height abovethe ground. In at least one form, this embodiment includes a mountingmember 1420 that may be fabricated from metal such as, for example,steel, stainless steel, etc. using conventional sheet metal drawing andstamping techniques. In other embodiments, the mounting member 1420 maybe cast or machined from metal, such as aluminum, steel or the like. Instill other embodiments, the mounting member 1420 may be molded from apolymer material. The flexible member 40 may comprise, for example,braided metal cable and have a length that is greater than an expectedcircumference of the tree portion T to which it is to be attached at theend of an expected or predetermined time period.

Referring first to FIGS. 40 and 41, a mounting member 1420 may be formedwith a mounting flange 1422 that has cup-like body portion 1424extending therefrom. The body portion 1424 includes a bottom 1426 and anannular wall 1428 that defines a receptacle area 1430 for receiving afriction-generating member 1460 therein. The friction generating member1460 may also be referred to herein as a ferrule. The bottom 1426includes a hole or opening 1432 that is sized to permit a flexiblemember 40 to pass therethrough as will be discussed in further detailbelow. A mounting hole 1434 is provided through the mounting flange 1422for attaching a first end 42 of the flexible member thereto. In at leastone embodiment, the mounting flange 1422 has a downturned strengtheninglip 1423 formed around its outer circumference to add strength to themounting flange 1422 in an effort to prevent the flexible member 40 fromtearing through the mounting flange 1422 during use. Other embodimentsmay employ a separate metal or polymer bushing (not shown) that ispressed into or otherwise mounted within the mounting hole 1434 toprevent the mounting flange 1422 from tearing or failing. As can be mostparticularly seen in FIGS. 44-46, in at least one embodiment, the firstend 42 of the flexible member 40 is passed through the mounting hole1434 and then reattached to a corresponding portion of the flexiblemember 40 by, for example, a conventional attachment ferrule 1435 thatis crimped using conventional methods. However, other methods ofattaching the first end of the flexible member 40 to the mounting flange1422 may be employed without departing from the spirit and scope of thepresent invention. The mounting flange 1422 may also be referred toherein as a “first portion” of the mounting member 1420 and the bottom1426 may also be referred to herein as a “second portion” of themounting member 1420.

FIGS. 42 and 43 illustrate one form of a friction generating member 1460that may be used in connection with the mounting member 1420. In variousembodiments, the friction generating member 1460 may comprise adisc-like member that is fabricated from a polymer or rubber or otherfriction-generating material. The friction-generating disc or nut 1460may have a circular shape with a centrally disposed friction hole 1462therethrough. The friction hole 1462 may be sized and shaped relative tothe size and shape of the flexible member 40 so that when a portion ofthe flexible member 40 is forced or otherwise entered into the hole1462, an amount of friction is generated therebetween. In at least oneembodiment, the friction generating member 1460 is provided with aninstallation slot or opening 1464 to facilitate insertion of a portionof the flexible member 40 into the friction hole 1462 duringinstallation. As can be most particularly seen in FIG. 41, in at leastone embodiment, the wall 1428 of the mounting member 1420 is slightlytapered in a frusto-conical fashion with a taper designated as “TP”. Invarious embodiments, the outer edge 1466 of the friction-generatingmember 1460 may be formed with a similar taper TP. See FIG. 43. In otherembodiments, the wall 1428 is not tapered. In still other embodiments,one or more dimples, formations rings, and/or slots may be formed in thewall 1428 to retain the friction generating member in sliding orslidable frictional engagement with the flexible member 40. In sucharrangements, for example, the friction generating member may beprovided in multiple segments. The mounting member 1420 and the frictiongenerating member or ferrule 1460 may also be referred to herein as a“mounting assembly”.

FIGS. 44-46 illustrate the assembly of the mounting member 1420 andfriction generating member 1460. FIG. 44 illustrates a second end 44 ofthe flexible member 40 prior to insertion through the hole 1432 in thebottom 1426 of the mounting member 1420. In at least one embodiment, thehole 1432 is sized and shaped relative to the size and shape of theflexible member 40 to permit the second end 44 thereof to be freelyinserted therethrough for ease of installation. In other embodiments,however, the hole 1432 may be sized and shaped relative to the size andshape of the flexible member 40 so as to create a sliding or slidablefrictional engagement between the flexible member 40 and the mountingmember 1420. FIG. 45 illustrates the mounting member 40 after the secondend 44 of the flexible mounting member 40 has been inserted through thehole 1432 in the mounting member 1420 and a portion of the flexiblemember 40 has been seated into the friction hole 1462 in the frictiongenerating member 1460. Once the flexible member 40 has been seated inthe friction hole 1462, the friction generating member 1460 is seatedinto the receptacle area 1430 in the mounting member 1420 by forciblysliding the friction generating member 1460 on the flexible member 40(represented by arrows “SF” in FIG. 45). FIG. 46 illustrates thefriction generating member 1460 seated within the receptacle area 1430in the mounting member 1420.

The apparatus 1410 may be employed to attach a variety of objects asdiscussed above to a tree using the various hanger member embodimentsdisclosed above. FIGS. 47-50 illustrate another hanger member 1500 thatmay be employed with the apparatus 1410 or other embodiments describedabove. As can be seen in those Figures, in at least one embodiment, thehanger member 1500 includes a planar body portion 1502 that defines afront face 1504 and a rear or (“tree-facing” face 1506). The bodyportion 1502 may have a length “L” and a width “W” that are greaterthan, equal to or less than the length and width, respectively, of theobject to be suspended from the tree. In the illustrated embodiment, thehanger member 1500 is provided with a centrally-disposed mounting lug1510 that protrudes outwardly from the rear-facing face 1506. Themounting lug 1510 has a passage 1512 therethrough for receiving aflexible mounting member therethrough. The passage 1512 may be sized andshaped relative to the size and shape of the flexible mounting memberemployed to permit the flexible member to pass freely therethrough forease of installation. Other embodiments may include more than onemounting lug 1510. In still other embodiments, the mounting lug 1510 maybe replaced with one or more hooks that simply permit the hanger memberto be hooked over the flexible member. In at least one embodiment, forexample, the hanger member 1500 may be molded or otherwise formed from apolymer material with the mounting lug(s) and/or hooks integrally formedwith the body portion 1502. In still other embodiments, the mountinglugs and/or hooks may be fabricated from material that is the same as ordissimilar to the material from which the body portion is fabricatedfrom and be attached thereto by adhesive, welding, fasteners, screws,rivets, brads, snap arrangements, etc. In other embodiments, the hangermember 1500 is machined or cast from metal material. In still otherembodiments, the hanger member may be fabricated from a block ofmaterial (e.g., polymer, metal, wood, etc.) and have a longitudinalpassage extending therethrough to enable the flexible member to passtherethrough.

As illustrated in FIG. 50, the object (a sign 12 is illustrated) may beattached to the hanger member 1500 by one or more fasteners 1520. Tofacilitate ease of installation, dimples 1503 or pilot holes may bepreformed in the body portion 1502 of the hanger member 1500 tofacilitate attachment of the object thereto. Where other forms offasteners are employed (e.g., rivets, brads, bolts, etc.) the holes 1503may be predrilled through the body portion 1502. FIG. 51 illustrates useof a piece of double sided tape 1530 on the front face 1504 of thehanger member 1500 for attaching the object thereto. Such double sidedtape 1530 may be used alone or in connection with any of the otherfastener forms discussed above for attaching the object to the hangermember 1500.

In other arrangements, the hanger member 1500 may be omitted. In sucharrangements, for example, the flexible member 40 may be woven throughholes or slots provided in the object itself. In still otherarrangements, the object may be formed with or have attached thereto,one or more hangers that can be used to support the object off of theflexible member.

The apparatus 1410 may be attached to a tree portion T in the mannerillustrated in FIG. 52. If the hanger member 1500 is to be used, priorto mounting the apparatus to the tree portion T, the user may insert thesecond end 42 of the flexible member 40 through the passage 1512 in themounting lug 1510 so that the hanger member 1500 is slidably received onthe flexible member 40. The user may then locate the apparatus 1410 at adesired height on the tree portion T by positioning the mounting member1420 on the backside of the tree portion T while positioning the hangermember 1500 adjacent the front side of the tree portion T. As usedherein, the term “backside of the tree” generally refers to the side ofthe tree portion T that is opposite to the side of the tree from whichthe hanger member and object will be suspended from (i.e., the “frontside”). The user then inserts the second end 44 of the flexible member40 through the hole 1432 in the bottom 1426 in the body portion 1424 ofthe mounting member 1420. While supporting the body portion 1424adjacent the backside of the tree, the user seats a portion of theflexible member 40 into the friction hole 1462 in a friction generatingmember 1460 and then slidably moves the friction generating member 1460on the flexible member 40 to seat it firmly into the receiving area 1430in the mounting member 1420 and thereby cinch the apparatus to the treeportion T at the desired height above the ground. Prior to cinching theflexible member 40, the user may slidably adjust the position of thehanger member 1500 on the flexible member. The object 12 may then beattached to the front face 1504 of the hanger member 1500 usingfasteners 1520 or any of the other attachment arrangements disclosedherein. In other methods, the object may have been pre-attached to thehanger member 1500 prior to installing the apparatus 1410 on the treeportion T.

As the tree portion T expands, the flexible member 40 will frictionallyslide through the friction hole 1462 in the friction-generating member1460. In various embodiments, the friction-generating member isfabricated from a polymer or rubber material that will serve to generatea sufficient amount of sliding or slidable friction with the flexiblemember as it extends therethrough. The amount of sliding or slidablefriction needed will depend upon the weight of the object to besuspended on the tree portion T. Such magnitude of sliding or slidablefriction should not be so great, however, as to ever prevent frictionalslippage between the flexible member 40 and the friction generatingmember 1460 as the tree portion T expands. As can be seen in FIG. 42, atleast one relief cut 1466 may be provided in the friction generatingmember 1460 to enable the friction generating member 1460 to be seatedin the mounting member 1420 thereby compressing the material definingthe friction hole 1462 into sliding or slidable frictional engagementwith the flexible member 40. The number, size, configuration andlocation of such relief cut(s) may vary and such variations are intendedto be within the scope of the appended claims. In still otherembodiments, the friction generating member may be provided in multiplepieces that, when seated within the mounting member, generate a desiredamount of sliding or slidable frictional engagement with the flexiblemember. As the tree portion continues to grow, the flexible member 40continues to frictionally slip through the friction generating member1460 to accommodate such growth until eventually all of the flexiblemember 40 pulls through the friction hole 1462 (without any humanintervention), at which point the apparatus may fall from the tree. Sucharrangement enables the object 12 to be suspended from the tree portionat a desired height above the ground for at least a desired period oftime without the need for human intervention during that time period andwithout the flexible member failing (e.g., breaking) or cutting throughthe outer bark of the tree and catastrophically damaging the tree.

As indicated above, in at least one embodiment, the outer edge 1466 ofthe friction-generating member 1460 may be formed with a taper TP thatis similar to the taper TP of the wall 1428 of the mounting member 1420.When employing this arrangement, as the tree expands, the outercircumference of the tree portion T will apply additional tension to theflexible member 40. Such additional tension will initially tend to drawthe friction generating member 1460 toward the bottom 1426 of themounting member 1420. Because the wall 1428 of the mounting member 1420tapers toward the bottom 1426 and the outer edge 1466 of thefriction-generating member 1460 is similarly tapered, the wall 1428 willtend to compress the friction generating member 1460 inwardly around theflexible member 40. Such arrangement therefore increases or at leastmaintains the frictional engagement with the portion of flexible member40 extending through the friction generating member until the amount ofadditional tension applied by the tree portion T exceeds the generatedfriction and the flexible member is then permitted to slide relativethereto to accommodate the growth of the tree portion T. For thoseembodiments that employ friction generating members that are fabricatedfrom a polymer or similar material that may tend to degrade over time asthe flexible member frictionally slides relative thereto, such taperedcompression configuration may serve to accommodate such degradation.That is, as the friction generating member continues to be drawn intothe receiving area toward the bottom of the mounting member, the wall1428 of the mounting member will further compress the frictiongenerating member into frictional engagement with the flexible member.Thus, such unique and novel arrangement comprises a mounting assemblythat “self-adjusts” or “self compensates” for degradation of thefriction generating member as the tree portion continues to grow.

Depending upon the weight of the object to be supported, the user mayinstall additional friction generating members or ferrules 1460 on theflexible member 40 to generate additional sliding frictional engagementwith the flexible member 40. The additional friction generating members1460 would be installed on the flexible member in back-to-back or“stacked” fashion. Depending upon the number of friction generatingmembers employed, some of the friction generating members 1460 may notbe received within the receptacle area 1430 in the mounting member 1420.Such unique and novel arrangement conveniently enables the user toattain a desired amount of sliding frictional engagement between themounting assembly and the flexible member that will be of sufficientmagnitude so as to support or suspend the object on the tree portion,yet enable a portion of the flexible member to slide therethrough as thetree portion expands without the need for human intervention.

In alternative arrangements wherein, for example, the object isfabricated from a metal or other material, the mounting member may beintegrally or otherwise formed or attached directly to the object. Insuch arrangement, the first end of the flexible member may be attachedto another portion of the object and the second end passed around thebackside of the tree portion T and inserted through the opening in themounting member portion. One or more friction generating members maythen be attached to the portion of flexible member protruding outthrough the mounting member portion and seated in the receiving areathereof. In such arrangements, for example, the excess flexible membermay be viewable from the front side of the tree portion T.

FIGS. 53-56 illustrate another apparatus 1410′ for supporting an objectsuch as a sign from a tree portion T at a desired height above theground. This embodiment employs a mounting member 1420′ that may be, forexample, substantially planar and have a hole or opening 1432′ that issized to permit a flexible member 40 to pass therethrough as will bediscussed in further detail below. Another mounting hole 1434′ isprovided through the mounting member 1420′ for attaching a first end 42of the flexible member 40 thereto. The mounting member 1420′ may befabricated from, for example, steel, stainless steel, aluminum,titanium, polymer, rubber, etc. In one embodiment, the mounting membermay have a downturned strengthening lip (not shown) formed around itsouter circumference in an effort to prevent the flexible member 40 fromtearing through the mounting member 1420′ during use. Other embodimentsmay employ a separate metal or polymer bushing (not shown) that ispressed into or otherwise mounted within the mounting hole 1434′ toprevent the mounting member 1420′ from tearing or failing.

The flexible member 40 may comprise braided metal cable and have alength that is greater than the expected circumference of the treeportion T to which it is to be attached at the end of an expected orpredetermined time period. In at least one embodiment, the first end 42of the flexible member 40 is passed through the mounting hole 1434′ andthen reattached to a corresponding portion of the flexible member 40 by,for example, a conventional attachment ferrule 1435 that is crimpedusing conventional methods. However, other methods of attaching thefirst end of the flexible member 40 to the mounting member 1420′ may beemployed without departing from the spirit and scope of the presentinvention.

FIGS. 55 and 56 illustrate the assembly of the mounting member 1420′ anda friction generating member 1460′. The friction generating member 1460′may be identical to the friction generating member 1460 described abovewithout the tapered outer edge. The mounting member 1420′ and thefriction generating member 1460′may be collectively referred to hereinas a “mounting assembly”. FIG. 55 illustrates a second end 44 of theflexible member 40 prior to insertion through the hole 1432′ in themounting member 1420′. In at least one embodiment, the hole 1432′ issized and shaped relative to the size and shape of the flexible member40 to permit the second end 44 thereof to be freely insertedtherethrough for ease of installation. In other embodiments, however,the hole 1432′ may be sized and shaped relative to the size and shape ofthe flexible member 40 so as to create a sliding or slidable frictionalengagement between the flexible member 40 and the mounting member 1420′.FIG. 56 illustrates the mounting member 40 after the second end 44 ofthe flexible mounting member 40 has been inserted through the hole 1432′in the mounting member 1420′ and a portion of the flexible member 40 hasbeen seated into the friction hole 1462′ in the friction generatingmember 1460′.

The apparatus 1410′ may be attached to a tree portion T as follows. Ifthe hanger member 1500 is to be used, prior to mounting the apparatus tothe tree portion T, the user may insert the second end 42 of theflexible member 40 through the passage 1512 in the mounting lug 1510 sothat the hanger member is slidably received on the flexible member 40.Thereafter, the user may locate the apparatus 1410′ at a desired heighton the tree portion T and thereafter position the mounting member 1420′on the backside of the tree portion T while positioning the hangermember 1500 adjacent the front side of the tree portion T. The user theninserts the second end 44 of the flexible member 40 through the hole1432′ in the mounting member 1420′. While supporting the mounting member1420 adjacent the backside of the tree portion T, the user seats aportion of the flexible member 40 protruding through the hole 1432′ inthe mounting member 1420′ into the friction hole 1462′ in the frictiongenerating member 1460′. The user then forcibly slides the frictiongenerating member 1460′ on the flexible member 40 to cinch the apparatus1410′ to the tree portion T at the desired height above the ground.Prior to cinching the flexible member 40, the user may slidably adjustthe position of the hanger member 1500 on the flexible member. Theobject 12 may then be attached to the front face 1504 of the hangermember 1500 using fasteners 1520 or any of the other attachmentarrangements disclosed herein. In other methods, the object may havebeen pre-attached to the hanger member 1500 prior to installing theapparatus 1410 on the tree portion T. As the tree portion T expands, theflexible member 40 will frictionally slide through the friction hole1462′ in the friction-generating member 1460′. Additional frictiongenerating members 1460′ may be installed as described above if desired.

In other arrangements, the hanger member 1500 may be omitted. In sucharrangements, for example, the flexible member 40 may be woven throughholes or slots provided in the object itself. In still otherarrangements, the object may be formed with or have attached thereto,one or more hangers that can be used to support the object off of theflexible member.

In alternative arrangements wherein, for example, the object isfabricated from a metal or other material, the hole 1432′ formed throughthe object. In such arrangement, the first end of the flexible membermay be attached to another portion of the object and the second endpassed around the backside of the tree portion T and inserted throughthe opening 1432′. One or more friction generating members may then beattached to the portion of flexible member protruding out through themounting member portion and seated in the receiving area thereof. Insuch arrangements, for example, the excess flexible member may beviewable from the front side of the tree portion T.

FIG. 57 illustrates another apparatus embodiment 1410″ of the presentinvention that employs a mounting member 1420′ as described above withone or more friction generating ferrules or slugs 1250 as describedabove. The apparatus 1410″ may be installed as described above, exceptthat one or more ferrules or slugs 1250 are used in place of thefriction generating member 1460′. The mounting member 1420′ and thefriction generating ferrule(s) may be collectively referred to herein asa “mounting assembly”. For example, after the second end of the flexiblemember 40 is passed through the hole 1432′ in the mounting member 1420′,the user installs a ferrule or slug 1250 on the second portion of theflexible cable 40 that protrudes out through the hole 1432′. In at leastone embodiment, the ferrule 1250 may be fabricated from aluminum orother metal material and have a bore 1252 therethrough that is sized toreceive the flexible member 40 (in the illustrated embodiment, a cable)therethrough. The user may then slide the ferrule 1250 into abuttingrelationship with the mounting member 1420′ as shown in FIG. 57. Theferrule 1250 is sized and shaped relative to the hole 1432′ in themounting member 1420′ such that the ferrule 1250 is prevent from passingtherethrough. The user may crimp or otherwise fasten the ferrule 1250 tothe flexible member 40 such that the apparatus 1410″ is cinched to thetree at the desired height, yet is movable thereon to accommodate treegrowth. The object may be supported on the flexible member using thehanger 1500 or any of the other arrangements described herein or theirequivalent structures. In still other arrangements, no hanger may beemployed as was discussed above.

FIGS. 58-62 illustrate another apparatus 1610 for supporting an objectsuch as a sign from a tree portion T at a desired height above theground. This embodiment employs a “mounting assembly” in the form of amounting member 1620 that may be for example substantially planar andhave a hole or opening 1632 therethrough that is sized and shapedrelative to the size and shape of the flexible member 40 such that whena portion of the flexible member 40 is seated therein, a desired amountof sliding frictional engagement is achieved between the mounting member1620 and the flexible member 40. The flexible member 40 may comprisebraided metal cable and have a length that is greater than the expectedcircumference of the tree portion T to which it is to be attached at theend of an expected or predetermined time period.

As can be most particularly seen in FIG. 58, the mounting member 1620further has an entry slot 1660 that extends from the outer edge 1621 ofthe mounting member 1620 into the hole or opening 1632. In theillustrated embodiment, the entry slot 1660 is somewhat tapered. Thatis, the open end 1662 of the entry slot 1660 is wider than the inner end1664 of the entry slot 1660 that extends into the hole or opening 1632.In at least one embodiment, the mounting member 1620 may be fabricatedfrom a polymer or other material that will slightly flex to enable theflexible member 40 to be seated in frictional engagement within the holeor opening 1632 in the mounting member 1620. In at least one form, thewidth of the second end 1664 of the entry slot 1660 is less than thediameter of the hole 1632. Such arrangement enables the flexible memberto be seated within the hole 1632. As can be seen in FIG. 58, the entryslot 1660 lies along a first axis FA-FA. The first axis FA-FA is alsosubstantially transverse to the centerline of the hole 1632.

As can also be seen in FIG. 58, another mounting hole 1634 is providedthrough the mounting member 1620 for attaching a first end 42 of theflexible member 40 thereto. In some embodiments (depending upon thematerial from which the mounting member 1620 is fabricated), a separatemetal or polymer bushing (not shown) is pressed into or otherwisemounted within the mounting hole 1634 to prevent the mounting member1620 from tearing or failing. As can also be seen in FIG. 58, in atleast some embodiments, the mounting hole 1634 is located on a secondaxis SA-SA that is substantially transverse to the first axis FA-FA. Ascan be seen in FIG. 59, in at least one embodiment, the first end 42 ofthe flexible member 40 (which is depicted therein as a braided metalcable) is passed through the mounting hole 1634 and then reattached to acorresponding portion of the flexible member 40 by, for example, aconventional attachment ferrule 1435 that is crimped using conventionalmethods. However, other methods of attaching the first end of theflexible member 40 to the mounting member 1620 may be employed withoutdeparting from the spirit and scope of the present invention.

FIGS. 59 and 60 illustrate a method of attaching the apparatus 1610 to atree portion T. If the hanger member 1500 is to be used, prior tomounting the apparatus to the tree “T”, the user may insert the secondend 44 of the flexible member 40 through the passage 1512 in themounting lug 1510 so that the hanger member is slidably received on theflexible member 40. Thereafter, the user may locate the apparatus 1610at a desired height on the tree portion T and thereafter position themounting member 1620 on the backside of the tree portion T whilepositioning the hanger member 1500 adjacent the front side of the treeportion T. The user then inserts a portion 43 of the flexible member 40down through the entry slot 1660 to seat it in the hole 1632 in themounting member 1620. The user then forcibly slides the mounting member1620 on the flexible member 40 to cinch the apparatus 1610 to the treeportion T at the desired height above the ground. Prior to cinching theflexible member 40, the user may slidably adjust the position of thehanger member 1500 on the flexible member. The object 12 may then beattached to the front face 1504 of the hanger member 1500 usingfasteners 1520 or any of the other attachment arrangements disclosedherein. In other methods, the object 12 may have been pre-attached tothe hanger member 1500 prior to installing the apparatus 1610 on thetree portion T. As the tree portion T expands, the first end portion 42of the flexible member 40 will pull in a first direction “FD” and theportion 43 of the flexible member 40 that is in sliding or slidablefrictional engagement with the mounting member 1620 will pull in asecond direction “SD”. See FIG. 61. As indicated above, in at least oneembodiment, the mounting hole 1634 lies along a second axis SA-SA thatis substantially transverse to the first axis FA-FA along which theentry slot 1660 lies. In such arrangement, the force F1 applied by thefirst end 42 of the flexible member 40 will oppose the force F2 appliedby the portion 43 of the flexible member 40. Such forces will generallybe applied along the second axis SA-SA in opposite directions. See FIG.62. Because the entry slot 1660 lies along the first axis FA-FA that istransverse to the second axis SA-SA, the portion 43 of the flexiblemember 40 that is in frictional engagement with the friction hole 1632will not tend to migrate back out of the entry slot 1660 and remainseated in the friction hole 1632.

The amount of sliding or slidable friction generated between theflexible member 40 and the friction hole or opening 1632 in the mountingmember 1620 may vary depending upon the size, shape, and composition ofthe flexible member as well as the size and shape of the friction holeor opening 1632 relative thereto. In addition, the sliding or slidablefriction may also be dependent upon the type of material from which themounting member 1620 is fabricated from and in particular, itsflexibility and coefficient of friction. The amount of sliding orslidable friction generated may also tend to increase as the portion 43of the flexible member engages the entry corner (designated as 1633 inFIG. 62) of the friction hole or opening 1632 as it enters therein.Other friction hole or opening arrangements may be employed in themounting member 1620 as well. For example, the friction hole or openingmay be drilled at a slight angle in an effort to reduce or adjust theamount of additional friction generated from contact with the entrycorner 1633 in the mounting member 1620. FIGS. 63 and 64 illustrate afriction hole 1632′ that has been drilled or otherwise formed throughthe mounting member 1620 at such an angle. As can be seen in FIG. 63,the hole axis or centerline CL-CL of the friction hole 1632′ extendsthrough the mounting member 1620 at an angle “A” such that it is notperpendicular with at least one of the outer surfaces of the mountingmember 1620. As can be seen therein, the angle “A” may be an acuteangle.

Various embodiments of the mounting member 1620 may employ other shapesand arrangements of entry slots. For example, FIG. 65 illustrates amounting member 1620′ that employs and entry slot 1660′ that has jaggededges 1661′. In those embodiments wherein the mounting member 1620 isfabricated from a metal material or material that has some malleability,the portions 1672, 1674 of the mounting member 1620′ adjacent the edges1661′ of the entry slot 1660′ may be bent out of plane in an effort toretain the flexible member 40 in sliding frictional engagement with themounting member 1620′ as the tree expands. See FIG. 66.

In alternative embodiments for example, the mounting member may actuallycomprise a portion of the object itself. Stated another way, a first endof the flexible member may be attached to the object and the frictiongenerating hole may be provided in another portion of the object. Anentry slot may be provided through an edge of the object to enable aportion of the flexible member to be frictionally seated in the opening.To affix the object to the tree portion T, the user wraps the freeportion of the flexible member around a portion of the tree portion Tand then seats the free portion into the friction generating hole tothereby cinch the object to the tree portion t. The flexible member isretained in sliding frictional engagement with the friction generatinghole so that, as the tree portion T expands (tree growth), the flexiblemember frictionally slips relative to the object to accommodate suchtree growth while remaining cinched to the tree. In other embodiments,the free portion of the flexible member may freely pass through anopening in the object and have at least one friction generating memberattached thereto that is sized such that it will not pass through theopening. As the tree portion grows, the friction generating memberpermits the free portion of the flexible member to frictionally sliderelative thereto to accommodate the additional tree growth whileremaining cinched to the tree portion.

Various embodiments of the present invention represent vast improvementsover prior methods and arrangements for attaching signs and otherobjects to growing trees. While several of the embodiments have beendescribed in connection with the use of various forms of hanger membersthat are particularly well-suited for attaching planar signs to trees,it will be understood that other hanger arrangements may be employed.For example, hanger members that are specifically configured to supportother objects such as bird feeders, ornaments, lights, etc. may beemployed in the manners described above to suspend the object from theflexible member. Clamps, hooks, etc. may also be hooked over or clippedto the various flexible members to suspend the object from the flexiblemember. Accordingly, the scope of protection afforded to the variousembodiments of the present invention should not be limited to use solelyin connection with the attachment of signs to trees.

The various apparatuses disclosed herein may also be effectivelyemployed with substantially rigid signs or other objects that have themounting member arrangement integrally-formed therewith. Thus, in suchembodiments, no separate mounting member or hanger member is required tosecure the object to the tree portion. In still other embodiments, theabove-described bushing or bushings may be installed in the objectitself and used in the above-described manners. Other embodimentswherein one or more friction generating members or ferrules are employedin connection with a flexible member, may include an object 12′ that hastwo holes provided therein. See FIG. 37A. In at least some embodiments,one end of the flexible member is passed through one hole and a retainerferrule or stop member or nut is non-movably applied thereto. The stopmember may be applied in the field or the flexible member may have thestop member non-movable attached thereto by the manufacturer. The secondend of the flexible member is passed through the other hole in theobject 12′ and one or more ferrules are slidably inserted thereon tocinch the object 12′ to the tree portion. The ferrule(s) are crimped inposition on the flexible member so that a desired amount of slidingfrictional fit is established between the flexible member and theferrule(s) such that the ferrule(s) will frictionally slide on theflexible member as the tree expands. In still other embodiments, asecond ferrule arrangement is slidably affixed to the first end of theflexible member in place of the non-movable stop member. In suchembodiment, both of the sliding ferrules serve to accommodate expansionof the tree in the above-described manners.

While the aforementioned embodiments are well-suited for use withobjects such as signs that are fabricated from somewhat rigid materials(e.g., metal, polymer, etc.), these embodiments may also be used inconnection with non-rigid signs and other objects or signs and objectsfabricated from somewhat thinner materials. In such applications forexample, a thrust washer may be inserted onto the cable between the stopmember and the object and another thrust washer may be inserted onto thecable between the ferrule and the object. Such thrust washers provide arigid bearing surface between the stop and the object and the ferruleand the object to prevent the stop and/or ferrule from pulling throughthe object.

Various embodiments of the present invention may comprise a flexiblemember that, when attached to the object or mounting member, serve tocompletely encircle the tree portion for at least the duration of theinstallation period. The flexible members, in combination with acorresponding stop member and/or ferrule(s) may be provided for use withobjects that have preformed installation holes therein as was discussedabove. The installation holes have a diameter that is larger than theflexible member's cross-sectional shape to facilitate slidable passageof the flexible member therethrough. When a stop member is employed, thestop member has a size and shape relative to one of the installationholes that will not permit the stop member to pass therethrough.Similarly, the ferrule(s) used on the second end portion of the flexiblemember are sized and shaped relative to the other installation hole inthe object so as to prevent the ferrule(s) from passing therethrough.

Thus, an embodiment of the present invention comprises an attachmentmechanism for attaching an object having at least two preformed holestherein to a portion of a growing tree for an expected installationperiod at a desired elevation above the ground. In at least one form,the mechanism comprises a cable that has a first end and a second endand a cross-sectional configuration that is sized and shaped to permitthe cable to pass through at least two of the preformed holes in theobject. The cable is provided with a length that may be calculated usingthe above-described method. The cable is provided with a length suchthat when the cable is coupled to the object, the cable and the objectserve to completely encircle the tree portion at least through theexpected installation period. A stop member is attached to the first endof the cable. The stop member may comprise a slug or ferrule that isnon-movably attachable to the first end of the cable by crimping orother suitable method. The stop member may also comprise a nut that isscrewed onto the first end of the cable and is otherwise non-movablethereon during use. In any case, the stop member has a configurationthat is sized and shaped to prevent the stop member from passing throughone of the preformed holes in the object. The mechanism furthercomprises a ferrule that is configured to be secured in a slidingfrictional engagement onto a portion of the second end of the cable inthe various manners described herein. A plurality of ferrules may beprovided in serial fashion on the cable to attain a desired amount ofsliding frictional fit, if desired. The ferrule(s), or at least a firstferrule has a configuration sized and shaped to prevent the ferrule frompassing through another one of the preformed holes in the object.

In another embodiment, the mechanism comprises a cable that has a firstend and a second end and a cross-sectional configuration that is sizedand shaped to permit the cable to pass through at least two of thepreformed holes in the object. The cable is provided with a length thatmay be calculated using the above-described method. The cable isprovided with a length such that when the cable is coupled to theobject, the cable and the object serve to completely encircle the treeportion at least through the expected installation period. At least onefirst ferrule is configured to be secured in a sliding frictionalengagement onto a portion of the first end of the cable. The firstferrule is sized and shaped to prevent the ferrule from passing througha preformed hole in the object. At least one second ferrule isconfigured to be secured in a sliding frictional engagement onto aportion of the second end of the cable. The second ferrule is sized andshaped to prevent the second ferrule from passing through another one ofthe preformed holes in the object.

The minimum amount of sliding frictional fit required to secure theapparatus and object attached thereto to the tree (or in otherembodiments, the sign itself) at the desired elevation above the groundmay depend upon the total or aggregate weight of the attachmentapparatus and object. That is, those objects that are heavier mayrequire a larger minimum amount of sliding frictional fit between theferrule(s) or friction generating member(s) and the cable than lighterobjects. For those embodiments that employ ferrules or frictiongenerating member(s), it is conceivable that plural ferrules or frictiongenerating members may be serially used to attain the desirable minimumamount of sliding frictional fit between the ferrule(s) or frictiongenerating member(s) and the cable. However, in such cases, the totalsliding frictional fit(s) should not be so great as to prevent theferrule(s) from sliding in response to the expanding tree.

In addition, the various embodiments of the present invention arewell-suited to be provided in kit form that enables the end user tospecifically tailor the apparatus to the particular sizes and types oftrees involved. For example, an exemplary kit may include a piece ofprecut flexible member, a mounting member and/or at least one hangermember. Other kit embodiments include a bulk amount of uncut flexiblemember, a plurality of mounting members and/or a plurality of hangermembers. Such kits may for example, include a spool of braided metalcable. Once the user determines how long the cable should be byemploying one of the above-described methods, that length of cable maybe cut from the spool of cable. Other kits may also include a chart thatsets forth the expected growth rates for various tree species. The chartmay, in at least one form, provide a recommended cable length for eachspecies based on the length of an installation period. For example, thechart may provide recommended cable lengths for installation periods of1 year, 5 years, 15 years, 20 years, etc. for selected tree species. Theuser may then determine the recommended cable length from the chart andcut the cable accordingly. Such arrangement enables the user to “tailor”the cable to a particular tree species for a particular installationperiod. Depending upon the type of object employed, the user may affixthe object directly to the tree or affix it to a hanger member or asupport member in the manner(s) described above. In still alternativearrangements, the user may simply elect to suspend the object (usingclips, hooks, etc.) from the cable once it has been secured to the treein the above-described manners. Still other kit embodiments may includea plurality of different hanger members and mounting members as well asa bulk amount of flexible member or a plurality of precut pieces offlexible member. The pieces of flexible member may be precut in onelength or they may be precut in a plurality of different lengths. Stillother kits may simply comprise a bulk amount of flexible member and aplurality of stop members and ferrules. Other kits may comprise aplurality of precut flexible members with a stop member attached to oneend thereof and a plurality of ferrules. The various kits may or may notinclude signs and may or may not include fasteners for fastening thesigns to the hanger or support member. Other kits may include one typeof sign and other kits may include different types of signs (e.g.,different sizes and/or compositions). Some kits may also include acrimping or swaging tool. Still other kits include a sign and a flexiblemember.

Some forms of the present invention do not require the use of any toolsto attach the apparatus to a tree. In some applications, depending uponthe type of hanger arrangement employed, a tool such as a screw drivermay be required to attach the sign or other object to the hanger. Otherembodiments require the use of a crimping or swaging tool.

Various embodiments of the present invention enable a sign or otherobject to be attached to a tree without damaging the inner bark orcambium layer for a predetermined period of time without the need tomanually adjust any part of the device during that predetermined timeperiod. While the amount of tree growth to occur during thatpredetermined time period may be estimated, the actual amount of treegrowth to occur can depend upon the growing conditions experiencedduring that time period and therefore may vary from that growthestimate. Accordingly, many of the embodiments disclosed herein mayautomatically detach from the tree when the tree's circumference exceedsthe length of the flexible member and/or the flexible member and thesupport or hanger member. Such unique and novel arrangements preventinadvertent tree damage should the tree's circumference exceed theestimated circumference and is otherwise not discovered by the user.

As discussed above, when signs are installed in wooded areas that arefrequented by squirrels, porcupines and similar animals, those animalscan destroy wooden backing boards and other materials that aresusceptible to being chewed by those animals. Many of the embodimentsdisclosed herein may employ metal components that will vastly reduce anylikelihood of experiencing such rodent damage.

Although the various embodiments of the devices have been describedherein in connection with certain disclosed embodiments, manymodifications and variations to those embodiments may be implemented.Also, where materials are disclosed for certain components, othermaterials may be used. The foregoing description and following claimsare intended to cover all such modification and variations.

What is claimed is:
 1. Apparatus for securing an object to a portion ofa living tree, said apparatus comprising: a cable including a first endand a second end and a length that is greater than an expectedcircumference of the tree portion at an end of a predetermined period oftime; a mounting member having a first portion secured to said first endof said cable, said mounting member further defining a receiving areahaving an opening therethrough that is dimensioned to receive saidsecond end of said cable therethrough after said cable has been wrappedaround a portion of the tree portion; and at least one frictiongenerating member including a friction hole sized to receivetherethrough in sliding frictional engagement along a portion of saidcable extending through said opening in said mounting member such thatwhen said at least one friction generating member is seated within saidreceiving area, said at least one friction generating member establishesan inwardly compressive force around said portion of cable extendingtherethrough to cinch said cable around the tree portion, said at leastone friction generating member sized relative to said opening to preventsaid at least one friction generating member from passing through saidopening in said mounting member and being dimensioned so as to interactwith said mounting member as the tree portion expands to thereby permitsaid cable portion to frictionally slip relative to said frictiongenerating member.
 2. The apparatus of claim 1 wherein the mountingmember comprises a portion of the object.
 3. The apparatus of claim 1wherein the mounting member is configured to support the object.
 4. Theapparatus of claim 1 further comprising a hanger member supportable onat least one of said mounting member and said cable and wherein thehanger member is configured to support the object.
 5. The apparatus ofclaim 4 wherein the object is attachable to the hanger member with afastener arrangement selected from the group of fastener arrangementsconsisting of screws, bolts, adhesive, clamps, paper fastener brads, anddouble-sided tape.
 6. The apparatus of claim 1 wherein the at least onefriction generating member comprises at least one ferrule.
 7. Theapparatus of claim 1 wherein at least one of said at least one frictiongenerating members comprises: a disc-like body; including said frictionhole therethrough.
 8. The apparatus of claim 7 further comprising anaccess slot extending from an outer perimeter of said disc-like body tosaid friction hole.
 9. The apparatus of claim 7 wherein said mountingmember includes a cup-like body portion that includes a tapered annularwall that defines said receiving area and wherein an outer edge of thedisc-like body of said friction generating member is formed at a taper.10. The apparatus of claim 1 wherein said at least one frictiongenerating member comprises at least two friction generating membersconfigured to be secured in a sliding frictional engagement onto saidportion of said cable extending through said opening in said mountingmember to cinch said cable around the tree portion, each said frictiongenerating member being dimensioned so as to interact with said mountingmember as the tree portion expands to thereby permit said cable portionto frictionally slip relative to said friction generating members. 11.Apparatus for securing an object to a portion of a living tree, saidapparatus comprising: a mounting member comprising: a body portioncomprising a closed bottom and an annular wall defining a cup-likereceptacle, said cup-like area defining a receiving area; and a holeextending through said closed bottom and wherein said apparatus furthercomprises: a cable including a first end attached to said body portionof said mounting member and a second end sized to pass through said holein said closed bottom, said cable including a length that is greaterthan an expected circumference of the tree portion at an end of apredetermined period of time; and at least one friction generatingmember sized to be received within said receiving area and including afriction hole sized to receive therethrough in sliding frictionalengagement along a portion of said cable extending through said cup-likereceptacle such that when said at least one friction generating memberis seated within said receiving area, said at least one frictiongenerating member establishes an inwardly compressive force around saidportion of cable extending therethrough to cinch said cable around thetree portion, said at least one friction generating member sizedrelative to said hole in said closed bottom to prevent said at least onefriction generating member from passing therethrough and beingdimensioned so as to interact with said mounting member as the treeportion expands to thereby permit said cable portion to frictionallyslip relative to said friction generating member, said at least onefriction generating member sized and configured to frictionally engagesaid annular wall of said body portion.
 12. The apparatus of claim 11wherein said annular wall of said body portion is tapered.
 13. Theapparatus of claim 12 wherein said at least one friction generatingmember includes a tapered perimeter configured to frictionally engagesaid tapered annular wall of said body portion.
 14. The apparatus ofclaim 11 wherein said at least one friction generating member comprisesat least two friction generating members configured to be secured in asliding frictional engagement onto the portion of said cable extendingthrough said opening in said mounting member to cinch the cable aroundthe tree portion, each said friction generating member being dimensionedso as to interact with said mounting member as the tree portion expandsto thereby permit said cable portion to frictionally slip relative tosaid friction generating members.
 15. The apparatus of claim 11 furthercomprising a flange on said body portion and wherein said first end ofsaid cable is attached to said flange.
 16. The apparatus of claim 11wherein said hole in said closed bottom is sized relative to said cableto permit said cable to freely pass therethrough.
 17. The apparatus ofclaim 11 further comprising a hanger member supportable on at least oneof said mounting member and said cable and wherein the hanger member isconfigured to support the object.
 18. The apparatus of claim 17 whereinthe object is attachable to the hanger member with a fastenerarrangement selected from the group of fastener arrangements consistingof screws, bolts, adhesive, clamps, paper fastener brads, anddouble-sided tape.
 19. Apparatus for securing an object to a portion ofa living tree, said apparatus comprising: a mounting member comprising:a body portion comprising a closed bottom and an annular wall defining acup-like receptacle, said annular wall tapering toward said closedbottom and defining a receiving area therein; a hole extending throughsaid closed bottom; and a flanged portion and wherein said apparatusfurther comprises: a cable including a first end attached to saidflanged portion of said mounting member and a second end sized to freelypass through said hole in said closed bottom, said cable including alength that is greater than an expected circumference of the treeportion at an end of a predetermined period of time; and at least onefriction generating member sized to be received within said receivingarea and including a friction hole sized to receive therethrough insliding frictional engagement along a portion of said cable extendingthrough said cup-like receptacle such that when said at least onefriction generating member is seated within said receiving area, said atleast one friction generating member establishes an inwardly compressiveforce around said portion of cable extending therethrough to cinch saidcable around the tree portion, said at least one friction generatingmember sized relative to said hole in said closed bottom to prevent saidat least one friction generating member from passing therethrough andbeing dimensioned so as to interact with said mounting member as thetree portion expands to thereby permit said cable portion tofrictionally slip relative to said friction generating member, said atleast one friction generating member sized and configured tofrictionally engage said annular wall of said body portion.